Compositional studies on succinoglycan-like extracellular water-soluble Rhizobium polysaccharides

This study reports structural information on extracellular, water-soluble polysaccharides from 5 different strains of Rhizobium, viz. R. trifolii J60, R. meliloti J1017, 202, 204 and 207. All the 5 polysaccharides had glucose and galactose in approximate molar ratio of 7:1. Methylation analysis revealed that the polysaccharides contained (1 leads to 3), (1 leads to 6), (1 leads to 4), (1 leads to 4, 1 leads to 6)-linked D-glucose residues, (1 leads to 3)-linked D-galactose and non-reducing terminal D-glucose attached to pyruvate. This structure was found to be exactly the same as that of succinoglycan, a succinic acid containing water-soluble polysaccharide elaborated by Alcaligenes faecalis var. myxogenes 10C3. The similarity of the structure of polysaccharides of two different Rhizobium species and also to the polysaccharide produced by Alcaligenes are discussed in terms of host specificity.     

Differences among the cell wall galactomannans from Aspergillus wentii and Chaetosartorya chrysella and that of Aspergillus fumigatus

The alkali extractable and water-soluble cell wall polysaccharides F1SS from Aspergillus wentii and Chaetosartorya chrysella have been studied by methylation analysis, 1D- and 2D-NMR, and MALDI-TOF analysis. Their structures are almost identical, corresponding to the following repeating unit: [→ 3)-β-D-Galf-(1 → 5)-β-D-Galf-(1 →] _n → mannan core. The structure of this galactofuranose side chain differs from that found in the pathogenic fungus Aspergillus fumigatus, in other Aspergillii and members of Trichocomaceae: [→ 5)-β-D-Galf-(1 →] _n → mannan core. The mannan cores have also been investigated, and are constituted by a (1 → 6)-α-mannan backbone, substituted at positions 2 by chains from 1 to 7 residues of (1 → 2) linked α-mannopyranoses. Published in 2004. This revised version was published online in July 2006 with corrections to the Cover Date.     

Production and physicochemical characterization of β-glucan produced by<Emphasis Type="Italic">Paenibacillus polymyxa</Emphasis> JB115

This study was conducted to develop a bacterial glucan as an animal feed additive. A novel glucan-producing bacterium.Paenibacillus polymyxa JB115, was isolated from Korean soil. The glucan, JB115-BG, produced byP. polymyxa JB115, was confirmed by TLC to be composed of glucose only. By examining FT-IR,¹H NMR, and¹³C NMR spectra, it was proven that JB115-BG has a β-(1→3)- and β-(1→6)-linked glucan structure. The particle size of JB115-BG was distributed in the range of 4–800 μm, with a mean value of 149.1 μm, and its molecular distribution ranged from 6.9∼3,103.7 kDa. It was also observed that 80% of the purified JB115-BG had a molecular distribution above 100 kDa. The obtained results suggest that the glucan JB115-BG can be used as an animal feed additive for the purpose of enhancing immunity.     

Lipopolysaccharide ofRhodospirillum salinarum 40: structural studies on the core and lipid A region

The structural elucidation of lipid A of the cell wall lipopolysaccharide (LPS) ofRhodospirillum salinarum 40 by chemical methods and laser desorption mass spectrometry revealed the presence of a mixed lipid A composed of three different 1,4 bisphosphorylated β(1→6)-linked backbone hexosaminyl-hexosamine disaccharides, i.e. those composed of GlCN→GlcN, 2,3-diamino-2,3-dideoxy-d-Glc-(DAG)→DAG, and DAG→GlcN. Lipid A ofR. salinarum contained preferentially 3-OH-18:0 and 3-OH-14:0 as amide-linked andcisΔ¹¹-18:1 and c19:0 as ester-linked fatty acids. The mass spectra of the liberated acyl-oxyacyl residues proved the concomitant presence of 3-O-(cisΔ¹¹-18:1)-18:0 and 3-O-(c19:0)-14:0 as the predominating diesters in this mixed lipid A. The glycosidically linked and the ester-linked phosphate groups of the backbone disaccharide were neither substituted by ethanolamine phosphorylethanolamine, nor by 4-amino-4-deoxy-l-arabinose, in contrast to most of the enterobacterial lipid As. In the core oligosaccharide fraction, a HexA (1→4)HexA(1→5)Kdo-trisaccharide was identified by methylation analysis. The terminal HexA (hexuronic acid) is possibly 4-OMe-GalA, a component described here as an LPS constituent for the first time. LPS ofR. salinarum showed a lethality in C57BL/10 ScSN (LPS-responder)-mice) of an order of 10⁻¹–10⁻² of that reported forSalmonella abortus equi LPS, and it was also capable of inducing TNFα and IL6 in macrophages of C57BL/10ScSN mice.     

Novel lipoarabinomannan-like lipoglycan (CdiLAM) contributes to the adherence of <Emphasis Type="Italic">Corynebacterium diphtheriae</Emphasis> to epithelial cells

The genus Corynebacterium is part of the phylogenetic group nocardioform actinomycetes. Members of this group have a characteristic cell envelope structure composed primarily of branched long-chain lipids, termed mycolic acids, and a rich number of lipoglycans such as lipoarabinomanans (LAM) and lipomannans. In this study, we identified a novel LAM variant isolated from Corynebacterium diphtheriae named CdiLAM. The key structural features of CdiLAM are a linear α-1→6-mannan with side chains containing 2-linked α-D-Manp and 4-linked α-D-Araf residues. The polysaccharide backbone is linked to a phosphatidylinositol anchor. In contrast to the LAMs of other members of actinomycetales, CdiLAM presents an unusual substitution at position 4 of α-1→6-mannan backbone by α-D-Araf. Unlike the non-fimbrial adhesin 62–72p, CdiLAM did not function as a hemagglutinin to human red blood cells. Experimental evidences pointed to CdiLAM as an adhesin of C. diphtheriae to human respiratory epithelial cells, thereby, contributing to the pathogenesis of diphtheria.     

Flavonol glycosides in the leaves ofTrillium apetalon Makino andT. kamtschaticum pallas

Seven flavonol glycosides were isolated from the leaves ofT. apetalon. They were identified chromatographically and spectrally to be: quercetin/kaempferol 3-O-α-arabinopyranosyl-(1→6)-β-galactopyranoside (TQ and TK), quercetin/kaempferol 3-O-[2‴-O-acetyl-α-arabinopyranosyl]-(1→6)-β-galactopyranoside (TAQ and TAK), quercetin 3-O-β-glucoside (ISQ), isorhamnetin 3-O-α-arabinopyranosyl-(1→6)-β-galactopyranoside (TI) and isorhamnetin 3-O-[2‴-O-acetyl-α-arabinopyranosyl]-(1→6)-β-galactopyranoside (TAI). TQ, TAQ, TI and TAI were major constituents. This is the first report on two new isorhamnetin-type glycosides, TI and TAI. The seven flavonol glycosides identical to those ofT. apetalon were isolated and identified in the leaves ofT. kamtschaticum; TQ and TAQ were also major components, but TI and TAI were only minor components. TI and TAI were not detected in the leaves ofT. tschonoskii. These leaf-flavonoid patterns were discussed from a chemosystematic point of view. Part 3 in the series “Studies of the flavonoids of the genusTrillium”. For Part 2 see Yoshitamaet al., (1997) J. Plant Res.110: 379–381.     

Isolation and characterization of an immunoenhancing glucan from alkaline extract of an edible mushroom, Lentinus squarrosulus (Mont.) Singer

A water-soluble glucan, isolated from the alkaline extract of the fruit bodies of an edible mushroom, Lentinus squarrosulus (Mont.) Singer was found to consist of (1→3,6)-linked, (1→3)-linked, (1→6)-linked, and terminal β-d-glucopyranosyl moieties in a relative proportion of approximately 1:2:1:1. This polysaccharide showed optimum activation of macrophages as well as splenocytes and thymocytes at 10 μg/mL. Structural investigation was carried out using sugar analysis, methylation analysis, periodate oxidation study, and NMR experiments (¹H, ¹³C, DEPT-135, DQF-COSY, TOCSY, NOESY, ROESY, HMQC, and HMBC). On the basis of above-mentioned experiments, the structure of the repeating unit of the polysaccharide was established as:     

Production of an extracellular polysaccharide byAgrobacterium sp DS3 NRRL B-14297 isolated from soil

A bacterium isolated from soil and identified asAgrobacterium sp produced a water-soluble extracellular polysaccharide capable of producing highly viscous solutions. Gas chromatographic analysis revealed a sugar composition of glucose, galactose and mannose in the molar ratio of 7.52.41, together with 3.7% (w/w) pyruvic acid. Methylation analyses showed the presence of (13)-, (14)- and (16)-linked glucose, (13)- and (14, 16)-linked galactose and a small portion of (13)-linked mannose residues. Succinic acid was not present. The molecular weight of the polysaccharide was estimated by light scattering to be 2×10⁶ Da. The viscosity of solutions containing the polysaccharide remained constant from pH 3 to 11, and decreased by 50% when heated from 5 to 55°C. Maximum yield of the polysaccharide, 20 g L^–1, was reached in 48 h at 30°C incubation.     

Structure and properties of carrageenan-like polysaccharide from the red alga Tichocarpus crinitus (Gmel.) Rupr. (Rhodophyta, Tichocarpaceae)

Sulfated polysaccharides occurring in the red algae Tichocarpus crinitus cell wall were fractionated and purified. NMR and FT-IR spectroscopy analyses revealed that the non-gelling fraction contained a sulfated galactans having a new carrageenan-like structure. It is built with alternatively linked 1,3-linked β-D-galactopyranosyl-2,4-disulphates and 1,4-linked 3,6-anhydro-α-D-galactopyranosyl residues. Minor amounts of its biosynthetic precursor were detected in a water-extracted specimen. Brief analysis of rheological and biological properties of the non-gelling fraction was carried out. The carrageenan-like polysaccharide from T. crinitus displayed the properties of “random coil” polymer at high temperature, and possesses high anticoagulant activity at low concentration.     

Extracellular polysaccharides of the genusRhizobium

This paper reports an investigation of the extracellular polysaccharides produced by 26 strains ofRhizobium andAgrobacterium. Strains ofRhizobium leguminosarum andR. phaseoli produced a water-soluble polysaccharide containing glucose, glucuronic acid and 4-0-methylglucuronic acid. These substances were also identified in the polysaccharide of a single strain fromLotus uliginosus. Glucose was the only detectable component in the polysaccharide produced by strains ofAgrobacterium radiobacter andA. tumefaciens. The polysaccharides obtained from slow-growing rhizobia were not freely water-soluble. Glucose, mannose, rhamnose, galactose and 4-0-methylglucuronic acid were identified as components of this extracellular material.These results are related to previous studies on rhizobial taxonomy and to the infection process in legumes.     

Distribution of cell wall components in<Emphasis Type="Italic"> Sphagnum</Emphasis> hyaline cells and in liverwort and hornwort elaters

Spiral secondary walls are found in hyaline cells of Sphagnum, in the elaters of most liverworts, and in elaters of the hornwort Megaceros. Recent studies on these cells suggest that cytoskeletal and ultrastructural processes involved in cell differentiation and secondary wall formation are similar in bryophytes and vascular plant tracheary elements. To examine differences in wall structure, primary and secondary wall constituents of the hyaline cells of Sphagnum novo-zelandicum and elaters of the liverwort Radula buccinifera and the hornwort Megaceros gracilis were analyzed by immunohistochemical and chemical methods. Anti-arabinogalactan–protein antibodies, JIM8 and JIM13, labeled the central fibrillar secondary wall layer of Megaceros elaters and the walls of Sphagnum leaf cells, but did not label the walls of Radula elaters. The CCRC-M7 antibody, which detects an arabinosylated (16)-linked -galactan epitope, exclusively labeled hyaline cells in Sphagnum leaves and the secondary walls of Radula elaters. Anti-pectin antibodies, LM5 and JIM5, labeled the primary wall in Megaceros elaters. LM5 also labeled the central layer of the secondary wall but only during formation. In Radula elaters, JIM5 and another anti-pectin antibody, JIM7, labeled the primary wall. The distribution of arabinogalactan–proteins and pectic polysaccharides restricted to specific wall types and stages of development provides evidence for the developmental and functional regulation of cell wall composition in bryophytes. Monosaccharide-linkage analysis of Sphagnum leaf cell walls suggests they contain polysaccharides similar to those of higher plants. The most abundant linkage was 4-Glc, typical of cellulose, but there was also evidence for xyloglucans, 4-linked mannans, 4-linked xylans and rhamnogalacturonan-type polysaccharides.Abbreviations AGP Arabinogalactan–protein - Araf Arabinofuranose - Fucp Fucopyranose - GalAp Galacturonopyranose - Galp Galactopyranose - GlcAp Glucuronopyranose - HGA Homogalacturonan - Manp Mannopyranose - RG Rhamnogalacturonan - Rhap Rhamnopyranose - XG Xyloglucan - Xylp Xylopyranose     

Isolation and structural determination of a unique polysaccharide containing mannofuranose from the cell wall of the fungus <Emphasis Type="Italic">Acrospermum compressum</Emphasis>

The alkali-extractable and water-soluble fungal polysaccharide F1SS isolated from the cell wall of Acrospermum compressum has been studied by methylation analyses, reductive cleavage and 1D- and 2D-NMR spectroscopy. The polysaccharide consists of a regular disaccharide repeating unit with the structure: The mannan core was obtained by mild hydrolysis of the polysaccharide F1SS and its structure was deduced to be composed of a skeleton of α-(1→6)-mannopyranan, with around 1 out of 11 residues substituted at position 2 by short chains (one to six units) of 2-substituted mannopyranoses. DOSY experiments provided molecular sizes of 60 kDa and 2.5 kDa for the polysaccharide F1SS and the mannan core, respectively. This is the first report of a fungal mannofuranose-containing cell wall polysaccharide.     

Novel teichulosonic acid from cell walls of some representatives of the genus Kribbella

Cell walls of each of five bacterial strains belonging to the genus Kribbella (family Nocardioidaceae, order Actinomycetales) contain a neutral polysaccharide (mannan) and teichulosonic acid of novel structure in different proportions. The novel teichulosonic acid found in strains VKM Ac-2500, VKM Ас-2568, VKM Ас-2572, and VKM Ас-2575 is a heteropolymer with an irregular structure where fragments I (predominant) alternate with fragments II (minor):The teichulosonic acid from Kribbella sp. VKM Ac-2527 has in general a structure similar to that above with the exception that the Pse residue is randomly glycosylated at O-4 with β-l-Rhap (along with α-d-Galp3OMe or α-d-Galp2,3OMe). The strain VKM Ac-2572 contained additionally teichuronic acid with the disaccharide repeating unit consisted of aminomannuronic acid and 2,3-diacetamido-2,3-dideoxy-α-glucopyranose. The mannan, a polysaccharide common to all of the strains, is built of (1→6)-linked α-d-mannopyranose substituted with α-d-mannopyranose at O-2. The structures of all the glycopolymers were established by a combination of chemical and NMR spectroscopic methods.     

Purification of alternanase by affinity chromatography

The enzyme alternanase, produced by Bacillus sp. NRRL B-21195, hydrolyzes alternan, a polysaccharide produced by certain strains of Leuconostoc mesenteroides that consists of glucose linked by alternating α(1→6), α(1→3) linkages. The main product of enzymatic hydrolysis by alternanase is a novel cyclic tetrasaccharide of glucose that also has alternating linkages between the glucose moieties. An improved purification scheme for alternanase has been developed that incorporates the use of isomaltosyl units linked to agarose for selectively binding the alternanase enzyme. Bound enzyme was eluted with 0.5 M sodium chloride and was nearly pure after this procedure. When followed by preparative isoelectric focusing, a single band of 117 kDa was measured when the purified protein was analyzed by HPLC size-exclusion chromatography/multiangle light scattering. The purification procedure can be scaled to permit large quantities of enzyme to be purified in high (36%) yield. Electronic Publication     

Structural investigation of a polysaccharide released by the cyanobacterium <Emphasis Type="Italic">Nostoc insulare</Emphasis>

The structural investigation of an extracellular polysaccharide released during photoautotrophic growth by the cyanobacterium Nostoc insulare is reported. After 60 days of cultivation, an average yield of purified, desalted, and freeze-dried released polysaccharide (RPS) of 0.9 g L⁻¹ medium was obtained. The apparent hydrodynamic volume, determined for RPS, was 1.1 × 10⁶ Da, and the average molecular weight was 2.8 × 10⁶ Da. No sulfate and only traces of pyruvate and acetate groups were detectable. A protein content of only 0.7% indicates a high degree of purity of RPS. The following constituent uronic acids and sugars were identified: glucuronic acid (GlcA), glucose (Glc), arabinose (Ara), and for the first time, cyanobacterial RPSs 3-O-methyl-arabinose (3-O-Methyl-Ara). Adapted from linkage analyses of untreated RPS and of RPS treated by means of reduction of uronic acids, mild acid hydrolysis with oxalic acid, or lithium degradation, respectively, the following partial structure of RPS is proposed, which possesses an arborisation built by 1,3,4-Glcp and a side chain built by 3-O-Methyl-Araf: →1)-Glcp-(3→1)-Glcp-[(3→1)-3-O-Methyl-Araf](4→1)-GlcAp-(4→).     

A polysaccharide from Lichina pygmaea and L. confinis supports the recognition of Lichinomycetes

The lichen-forming order Lichinales, generally characterized by prototunicate asci and the development of thalli with cyanobacteria, has recently been recognized as a separate class of ascomycetes, Lichinomycetes, as a result of molecular phylogenetic studies. As alkali and water-soluble (F1SS) polysaccharides reflect phylogeny in other ascomycetes, a polysaccharide from Lichina pygmaea and L. confinis was purified and characterized to investigate whether these F1SS compounds in the Lichinomycetes were distinctive. Nuclear magnetic resonance (NMR) spectroscopy and chemical analyses revealed this as a galactomannan comprising a repeating unit consisting of an α-(1→6)-mannan backbone, mainly substituted by single α-galactofuranose residues at the O-2- or the O-2,4- positions linked to a small mannan core. With the exception of the trisubstituted mannopyranose residues previously described in polysaccharides from other lichens belonging to orders now placed in Lecanoromycetes, the structure of this galactomannan most closely resembles those found in several members of the Onygenales in Eurotiomycetes. Our polysaccharide data support molecular studies showing that Lichina species are remote from Lecanoromycetes as the galactofuranose residues are in the α-configuration. That the Lichinomycetes were part of an ancestral lichenized group can not be established from the present data because the extracted polysaccharide does not have the galactofuranose residue in the β configuration; however, the data does suggest that an ancestor of the Lichinomycetes contained a mannan and was part of an early radiation in the ascomycetes.     

Chain elongation of pectic β-(1→4)-galactan by a partially purified galactosyltransferase from soybean (<Emphasis Type="Italic">Glycine max</Emphasis> Merr.) hypocotyls

Pectin is one of the major cell wall polysaccharides found in dicotyledonous plants. We have solubilized and partially purified a β-(1→4)-galactosyltransferase (GalT) involved in the synthesis of the β-(1→4)-galactan side chains of pectin. The enzyme protein was almost completely solubilized by mixing a crude microsomal preparation of etiolated 6-day-old soybean (Glycine max Merr.) hypocotyls with a detergent, Triton X-100 (0.75%, w/v), in buffer. The solubilized enzyme was partially purified by ion-exchange chromatography. The crude membrane-bound GalT transferred Gal from UDP-Gal onto 2-aminobenzamide (AB)-derivatized β-(1→4)-galactoheptaose (Gal₇-AB), leading to the formation of Gal_8–11-AB by attachment of a series of one to four galactosyl residues; this is similar to what has previously been observed for 2-aminopyridine-derivatized β-(1→4)-galactooligomer acceptors (Konishi et al. in Planta 218:833–842, 2004). The partially purified GalT, by contrast, was able to transfer more than 25 galactosyl residues and elongated the chains to about Gal₃₅-AB, thus almost reaching the length (43–47 Gal units) of native β-(1→4)-galactan side chains found in pectic polysaccharides from soybean cotyledons (Nakamura et al. in Biosci Biotechnol Biochem 66:1301–1313, 2002). Enzyme activity increased with increasing chain length of β-(1→4)-galactooligomers and reached maximal activity at heptaose, whereas galactooligomers higher than heptaose showed lower acceptor efficiency. Sugars described in this paper belong to the d-series unless otherwise noted.     

Novel Mutations Found in Two Genes of Thai Patients with Isolated Methylmalonic Acidemia

Molecular genetic analysis of three patients diagnosed with isolated methylmalonic acidemia (MMA) revealed that one was mut ⁰ MMA, with a mutation in the MUT gene encoding the l-methylmalonyl-CoA mutase (MCM), and two were cblB MMA, with mutations in the MMAB gene required for synthesizing the deoxyadenosylcobalamin cofactor of MCM. The mut ⁰ patient was homozygous for a novel nonsense mutation in MUT, p.R31X (c.167C → T), and heterozygous for three previously described polymorphisms, p.K212K (c.712A → G), p.H532R (c.1671A → G), and p.V671I (c.2087G → A). The new MMAB mutation, p.E152X (c.454G → T), was found to be homozygous in one cblB patient and heterozygous in the other patient, who also had four intron polymorphisms in this gene.     

Extraction, characterization of Astragalus polysaccharides and its immune modulating activities in rats with gastric cancer

One major polysaccharide fractions, glucose, were isolated from the polysaccharides extract of Astragalus (AP), a valuable traditional Chinese medicine, using thin-layer chromatography (TLC) and Sephadex G-100 chromatography. HPLC and IR methods were used for a qualitative and quantitative determination of from polysaccharides of Astragalus. The HPLC method was validated for linearity, precision and accuracy. The results indicated that polysaccharides of Astragalus is an α-(1 → 4)-d-glucan with α-(1 → 6)-linked branches attached to the O-6 of branch points. Bioactivity tests showed that polysaccharides of Astragalus is active for spleen lymphocytes proliferation. The polysaccharides also presented anti-inflammatory activities. These data together suggest that polysaccharides of Astragalus presents significant immune modulating activity, thus supporting the popular use of the polysaccharides in the treatment of gastric cancer diseases.     

Chemical characterization of cell-wall polysaccharides from tank-cultivated and wild plants ofDelesseria sanguinea (Hudson) Lamouroux (Ceramiales,delesseriaceae): culture patterns and potent anticoagulant activity

Tank cultivation ofDelesseria sanguinea was investigated in order to manipulate conditions for vegetative growth and to provide biomass for the analysis of cell wall polysaccharides. Seasonality is subject to short-day photoperiodic control. Night-break or long-day conditions prevented fertility in tetrasporophytes and gametophytes and triggered outgrowth of new blades. Long-day illuminations allowed a 1% daily growth rate. Seawater temperature below 13 °C was necessary for inducing formation of new blades. Both wild and cultivated ofD. sanguinea plants contained a non gelling sulfated heteropolysaccharide composed of a galactosyl backbone branched with xylosyl residues. The hot water extract at neutral pH displayed the highest anticoagulant activity (5 μg ml^-1 polysaccharide concentration in APTT clotting assay). No obvious differences were found in polysaccharide chemical composition and properties between gametophytes and sporophytes or between cultivated and wild plants.