β-N-Acetylhexosaminidase-catalysed synthesis of non-reducing oligosaccharides

A large panel of fungal β-N-acetylhexosaminidases was tested for the regioselectivity of the β-GlcNAc transfer onto galacto-type acceptors ( -galactose, lactose, 2-acetamido-2-deoxy- -galactopyranose). A unique, non-reducing disaccharide β- -GlcpNAc-(1→1)-β- -Galp and trisaccharides β- -GlcpNAc-(1→4)-β- -GlcpNAc-(1→1)-β- -Galp, β- -Galp-(1→4)-β- -Glcp-(1→1)-β- -GlcpNAc and β- -Galp-(1→4)-α- -Glcp-(1→1)-β- -GlcpNAc were synthesised under the catalysis of the β-N-acetylhexosaminidase from the Aspergillus flavofurcatis CCF 3061 with -galactose and lactose as acceptors. The use of 2-acetamido-2-deoxy- -galactopyranose as an acceptor with the β-N-acetylhexosaminidases from A. flavofurcatis CCF 3061, A. oryzae CCF 1066 and A. tamarii CCF 1665 afforded only β- -GlcpNAc-(1→6)- -GalpNAc.     

N-Acetylhexosamine triad in one molecule: Chemoenzymatic introduction of 2-acetamido-2-deoxy-β-d-galactopyranosyluronic acid residue into a complex oligosaccharide

A complex trisaccharide β-d-GalpNAcA-(1 → 4)-β-d-GlcpNAc-(1 → 4)-d-ManpNAc (3) was prepared in a good yield (35%) in a transglycosylation reaction catalyzed by β-N-acetylhexosaminidase from Talaromyces flavus using p-nitrophenyl 2-acetamido-2-deoxy-β-d-galacto-hexodialdo-1,5-pyranoside (1) as a donor followed by the in situ oxidation of the aldehyde functionality by NaClO₂. The disaccharide β-d-GlcpNAc-(1 → 4)-d-ManpNAc (2) was used as galactosyl acceptor. A disaccharide β-d-GalpNAcA-(1 → 4)-d-GlcpNAc (4; 39%) originated as a by-product in the reaction. Oligosaccharides comprising a carboxy moiety at C-6 are shown to be very efficient ligands to natural killer cell activation receptors, particularly to human receptor CD69. Thus, oxidized trisaccharide 3 is the best-known oligosaccharidic ligand to this receptor, with IC₅₀ = 2.5 × 10⁻⁹ M. The presented method of introducing a β-d-GalpNAcA moiety into carbohydrate structures is versatile and can be applied in the synthesis of other complex oligosaccharides.     

New cell wall glycopolymers of the representatives of the genus Kribbella

Each of the cell walls of four representatives of the genus Kribbella (order Actinomycetales; suborder Propionibacterineae; family Nocardioidaceae) contains a neutral polysaccharide and an acidic polysaccharide with unusual structures. Common to all four strains studied is a mannan with the following repeating unit: In the cell wall of the strain VKM Ac-2541, a teichulosonic acid was identified with a monosaccharide component that has not hitherto been found in Gram-positive bacteria, viz., pseudaminic acid, and an unusual linkage type in the polymeric chain,

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where R = Н (45%), α-d-Galp3OMe (37%) or α-d-Galp2,3OMe (18%).The anionic cell wall components of three other strains are represented by teichuronic acids with a rare constituent, viz., a diaminosugar, 2,3-diacetamido-2,3-dideoxyglucopyranose. The structures of their repeating units differ in the nature of the acidic components:→4)-β-d-Manp2,3NAcA-(1→6)-α-d-Glcp2,3NAc-(1→ (VKM Ас-2538 and VKM Ас-2540) and →4)-β-d-ManpNAcA-(1→6)-α-d-Glcp2,3NAc-(1→ (VKM Ас-2539).The structures of all the glycopolymers were established by chemical and NMR spectroscopic methods; they are identified in Gram-positive bacteria for the first time.     

Large-scale production of the carbohydrate portion of the sialyl–Tn epitope, α-Neup5Ac-(2→6)- -GalpNAc, through bacterial coupling

α-Neup5Ac-(2→6)- -GalpNAc, the carbohydrate portion of sialyl–Tn epitope of the tumor-associated carbohydrate antigen, was prepared by a whole-cell reaction through the combination of recombinant Escherichia coli strains and Corynebacterium ammoniagenes. Two recombinant E. coli strains overexpressed the CMP-Neup5Ac biosynthetic genes and the α-(2→6)-sialyltransferase gene of Photobacterium damsela. C. ammoniagenes contributed to the production of UTP from orotic acid. α-Neup5Ac-(2→6)- -GalpNAc was accumulated at 87 mM (45 g/L) after a 25-h reaction starting from orotic acid, N-acetylneuraminic acid, and 2-acetamide-2-deoxy- -galactose.     

Structure of the Type IX Group B Streptococcus Capsular Polysaccharide and Its Evolutionary Relationship with Types V and VII

The Group B Streptococcus capsular polysaccharide type IX was isolated and purified, and the structure of its repeating unit was determined. Type IX capsule →4)[NeupNAc-α-(2→3)-Galp-β-(1→4)-GlcpNAc-β-(1→6)]-β-GlcpNAc-(1→4)-β-Galp-(1→4)-β-Glcp-(1→ appears most similar to types VII and V, although it contains two GlcpNAc residues. Genetic analysis identified differences in cpsM, cpsO, and cpsI gene sequences as responsible for the differentiation between the three capsular polysaccharide types, leading us to hypothesize that type V emerged from a recombination event in a type IX background.     

Structural studies by NMR spectroscopy of the major oligomers from alkali-degraded arabinoigalactan from Larix occidentalis

Oligomers with terminal metasaccharinic acid residues have been derived from branches on the main chain of arabinogalactan by alkaline degradation. The major oligomers present have been studied by NMR. Individual oligomers existed as epimeric pairs in the approximate ratio 1.5:1. This study confirmed the presence of branches consisting of a single β- -Ga1p residue, of two or three β- -Galp residues linked (1→6) or of two β-D-Ga1p residues linked (1→6) with the proximate residue further substituted at O-3 by an α- -arabinofuranosyl residue.     

Synthesis of Haemophilus influenzae carbohydrate surface antigens

The pathogenic bacteria Haemophilus influenzae, causing, i.a., meningitis and otitis, contain both capsular and lipopolysaccharide surface antigens. The syntheses of several oligosaccharides corresponding to native H. influenzae polysaccharide structures is outlined with an emphasis on synthetically challenging features. Hence, the synthesis of a branched inner core lipopolysaccharide tetrasaccharide structure, α- , -Hepp-(13)-[β- -Glcp-(14)]-α- , -Hepp-(15)-αKdo, containing the unusual higher carbon sugars -glycero- -manno-heptose and Kdo is described, as well as the assembly of di- and trimers of the repeating unit of the capsular polysaccharides of serotype c,[−4)-3-OAc-β- -GlcpNAc-(13)-α- -Galp-(1-PO⁻₃−] and serotype f[−3)-β- -GalpNAc-(14)-3-OAc-α- -GalpNAc-(1-PO⁻₃], both linked via anomeric phospodiester linkages. Also efforts towards the synthesis of the repeating unit of the capsular polysaccharide of serotype e,3)-β- -GlcpNAc-(14)-[β- -Fruf-(23)]-β- -ManpNAcA-(1, containing a β-fructofuranosidic residue, is discussed. All synthetic derivates are spacer-equipped to allow formation of glycoconjugates for biological applications.     

Capsular and extracellular polysaccharides from Rhizobium microsymbionts of Acacia decurrens

The capsular polysaccharide produced by a Rhizobium isolated from a root nodule of Acacia decurrens is composed of 3-O-methyl- -rhamnose: -rhamnose: - mannose: -glucose: -galacturonic acid in the molar ratios of 1:2:2:4:1. The extracellular polysaccharide is similarly constituted. Structural analyses indicate a decasaccharide repeating-unit in which the -rhamnosyl groups occur as single-unit side-chains. The 3-O-methyl- -rhamnosyl and one of the α- -rhamnosyl groups are (1→6)-linked to two of the -glucosyl residues. The other α- -rhamnosyl group is (1→4)-linked to the -galacturonic acid residue. The main-chain residues are all (1→3)-linked, and are partially identified as -(1→3)-α- -GalpA-(1→3)-α- -Manp- (1→3)-α- -Glcp-(1→3)-.     

Enzymatic synthesis of α- -fucosyl-N-acetyllactosamines and 3′-O-α- -fucosyllactose utilizing α- -fucosidases

An α- -fucosidase from porcine liver produced α- -Fuc-(1→2)-β- -Gal-(1→4)- -GlcNAc (2′-O-α- -fucosyl-N-acetyllactosamine, 1) together with its isomers α- -Fuc-(1→3)-β- -Gal-(1→4)- -GlcNAc (2) and α- -Fuc-(1→6)-β- -Gal-(1→4)- -GlcNAc (3) through a transglycosylation reaction from p-nitrophenyl α- -fucopyranoside and β- -Gal-(1→4)- -GlcNAc. The enzyme formed the trisaccharides 1–3 in 13% overall yield based on the donor, and in the ratio of 40:37:23. In contrast, transglycosylation by Alcaligenes sp. α- -fucosidase led to the regioselective synthesis of trisaccharides containing a (1→3)-linked α- -fucosyl residue. When β- -Gal-(1→4)- -GlcNAc and lactose were acceptors, the enzyme formed regioselectively compound 2 and α- -Fuc-(1→3)-β- -Gal-(1→4)- -Glc (3′-O-α- -fucosyllactose, 4), respectively, in 54 and 34% yields, based on the donor.     

Structure and Biosynthesis of Two Exopolysaccharides Produced by Lactobacillus johnsonii FI9785

Exopolysaccharides were isolated and purified from Lactobacillus johnsonii FI9785, which has previously been shown to act as a competitive exclusion agent to control Clostridium perfringens in poultry. Structural analysis by NMR spectroscopy revealed that L. johnsonii FI9785 can produce two types of exopolysaccharide: EPS-1 is a branched dextran with the unusual feature that every backbone residue is substituted with a 2-linked glucose unit, and EPS-2 was shown to have a repeating unit with the following structure: -6)-α-Glcp-(1–3)-β-Glcp-(1–5)-β-Galf-(1–6)-α-Glcp-(1–4)-β-Galp-(1–4)-β-Glcp-(1-. Sites on both polysaccharides were partially occupied by substituent groups: 1-phosphoglycerol and O-acetyl groups in EPS-1 and a single O-acetyl group in EPS-2. Analysis of a deletion mutant (ΔepsE) lacking the putative priming glycosyltransferase gene located within a predicted eps gene cluster revealed that the mutant could produce EPS-1 but not EPS-2, indicating that epsE is essential for the biosynthesis of EPS-2. Atomic force microscopy confirmed the localization of galactose residues on the exterior of wild type cells and their absence in the ΔepsE mutant. EPS2 was found to adopt a random coil structural conformation. Deletion of the entire 14-kb eps cluster resulted in an acapsular mutant phenotype that was not able to produce either EPS-2 or EPS-1. Alterations in the cell surface properties of the EPS-specific mutants were demonstrated by differences in binding of an anti-wild type L. johnsonii antibody. These findings provide insights into the biosynthesis and structures of novel exopolysaccharides produced by L. johnsonii FI9785, which are likely to play an important role in biofilm formation, protection against harsh environment of the gut, and colonization of the host.     

6-<Emphasis Type="Italic">O</Emphasis>-Sulfo sialylparagloboside and sialyl Lewis X neo-glycolipids containing lactamized neuraminic acid: Synthesis and antigenic reactivity against G159 monoclonal antibody

Synthesis and antigenic reactivity of 6-O-sulfo sialylparagloboside (SPG) and sialyl Lewis X (sLe^X) neo-glycolipids containing lactamized neuraminic acid are described. The suitably protected GlcNAc-β (1 → 3)-Gal-β (1 → 4)-GlcOSE derivative was glycosylated with NeuTFAc-α (2 → 3)-Gal imidate to give NeuTFAc-α (2 → 3)-Galβ (1 → 4)-GlcNAc-β (1 → 3)-Gal-β (1 → 4)-GlcOSE pentasaccharide. The partial N,O-deacylation in the NeuTFAc-α (2→3)-Gal part afforded N-deacetylated SPG derivative which was converted to the desired oligosaccharide containing lactamized neuraminic acid. Similar treatment of the sLe^X hexasaccharide derivative, NeuTFAc-α (2 → 3)-Gal-β (1 → 4) [Fuc-α (1 →3)]-GlcNAc-β (1 → 3)-Gal-β (1 → 4)-GlcOSE, gave the key hexasaccharide intermediate containing lactamized neuraminic acid. These suitably protected SPG and sLe^x oligosaccharides were converted stepwise into the desired neo-glycolipids (GSC-551 and GSC-552) by the coupling with 2-(tetradecyl)hexadecanol, 6-O-sulfation at C-6 of the GlcNAc residure, and complete deprotection.Both lactamized-sialyl 6-O-sulfo SPG (GSC-551) and sLe^x (GSC-552) neo-glycolipids were clearly recognized with G159 monoclonal antibody showing that both the lactamized neuraminic acid and the 6-O-sulfate at C-6 of GlcNAc would be involved in the G159-defined determinant. However, the Fuc residue and the lipophilic (ceramide) part may not be critical for this recognition. Published in 2005Synthetic studies on sialoglycoconjugates, Part 138. For part 136, see Ref [1], and for part 137, see Ref [19].     

Saponins from Albizzia lucida

Three main saponins were isolated from the seeds of Albizzia lucida. Their structures were established by spectral analyses and chemical and enzymatic transformations as 3-O-[β- -xylopyranosyl(1→2)-α- -arabinopyranosyl (1→6)] [β- -glucopyranosyl (1→2)] β- -glucopyranosyl echinocystic acid; 3-O-[α- -arabinopyranosyl (1→6)][β- -glucopyranosyl (1→2)]-β- -glucopyranosyl echinocystic acid and 3-O-[β- -xylopyranosyl (1→2)-β- -fucopyranosyl (1→6)-2-acetamido-2-deoxy-β- -glucopyranosyl echinocystic acid, characterized as its methyl ester.     

Hydrolysis of β-1,3/1,6-glucan by glycoside hydrolase family 16 endo-1,3(4)-β-glucanase from the basidiomycete Phanerochaete chrysosporium

When Phanerochaete chrysosporium was grown with laminarin (a β-1,3/1,6-glucan) as the sole carbon source, a β-1,3-glucanase with a molecular mass of 36 kDa was produced as a major extracellular protein. The cDNA encoding this enzyme was cloned, and the deduced amino acid sequence revealed that this enzyme belongs to glycoside hydrolase family 16; it was named Lam16A. Recombinant Lam16A, expressed in the methylotrophic yeast Pichia pastoris, randomly hydrolyzes linear β-1,3-glucan, branched β-1,3/1,6-glucan, and β-1,3-1,4-glucan, suggesting that the enzyme is a typical endo-1,3(4)-β-glucanase (EC 3.2.1.6) with broad substrate specificity for β-1,3-glucans. When laminarin and lichenan were used as substrates, Lam16A produced 6-O-glucosyl-laminaritriose (β-d-Glcp-(1–>6)-β-d-Glcp-(1–>3)-β-d-Glcp-(1–>3)-d-Glc) and 4-O-glucosyl-laminaribiose (β-d-Glcp-(1–>4)-β-d-Glcp-(1–>3)-d-Glc), respectively, as one of the major products. These results suggested that the enzyme strictly recognizes β-d-Glcp-(1–>3)-d-Glcp at subsites −2 and −1, whereas it permits 6-O-glucosyl substitution at subsite +1 and a β-1,4-glucosidic linkage at the catalytic site. Consequently, Lam16A generates non-branched oligosaccharide from branched β-1,3/1,6-glucan and, thus, may contribute to the effective degradation of such molecules in combination with other extracellular β-1,3-glucanases.     

Secondary Cell Wall Polymers of Enterococcus faecalis Are Critical for Resistance to Complement Activation via Mannose-binding Lectin

The complement system is part of our first line of defense against invading pathogens. The strategies used by Enterococcus faecalis to evade recognition by human complement are incompletely understood. In this study, we identified an insertional mutant of the wall teichoic acid (WTA) synthesis gene tagB in E. faecalis V583 that exhibited an increased susceptibility to complement-mediated killing by neutrophils. Further analysis revealed that increased killing of the mutant was due to a higher rate of phagocytosis by neutrophils, which correlated with higher C3b deposition on the bacterial surface. Our studies indicated that complement activation via the lectin pathway was much stronger on the tagB mutant compared with wild type. In concordance, we found an increased binding of the key lectin pathway components mannose-binding lectin and mannose-binding lectin-associated serine protease-2 (MASP-2) on the mutant. To understand the mechanism of lectin pathway inhibition by E. faecalis, we purified and characterized cell wall carbohydrates of E. faecalis wild type and V583ΔtagB. NMR analysis revealed that the mutant strain lacked two WTAs with a repeating unit of →6)[α-l-Rhap-(1→3)]β-d-GalpNAc-(1→5)-Rbo-1-P and →6) β-d-Glcp-(1→3) [α-d-Glcp-(1→4)]-β-d-GalpNAc-(1→5)-Rbo-1-P→, respectively (Rbo, ribitol). In addition, compositional changes in the enterococcal rhamnopolysaccharide were noticed. Our study indicates that in E. faecalis, modification of peptidoglycan by secondary cell wall polymers is critical to evade recognition by the complement system.     

Transglycosidase activity of Bifidobacterium adolescentis DSM 20083 α-galactosidase

Bifidobacterium adolescentis, a gram-positive saccharolytic bacterium found in the human colon, can, alongside other bacteria, utilise stachyose in vitro thanks to the production of an α-galactosidase. The enzyme was purified from the cell-free extract of Bi. adolescentis DSM 20083^T. It was found to act with retention of configuration (α→α), releasing α-galactose from p-nitrophenyl galactoside. This hydrolysis probably operates with a double-displacement mechanism, and is consistent with the observed glycosyltransferase activity. As α-galactosides are interesting substrates for bifidobacteria, we focused on the production of new types of α-galactosides using the transgalactosylation activity of Bi. adolescentisα-galactosides. Starting from melibiose, raffinose and stachyose oligosaccharides could be formed. The transferase activity was highest at pH 7 and 40 °C. Starting from 300 mM melibiose a maximum yield of 33% oligosaccharides was obtained. The oligosaccharides formed from melibiose were purified by size-exclusion chromatography and their structure was elucidated by NMR spectroscopy in combination with enzymatic degradation and sugar linkage analysis. The trisaccharide α-d-Galp-(1 → 6)-α-d-Galp-(1 → 6)-d-Glcp and tetrasaccharide α-d-Galp-(1 → 6)-α-d-Galp-(1 → 6)-α-d-Galp-(1 → 6)-d-Glcp were identified, and this indicates that the transgalactosylation to melibiose occurred selectively at the C-6 hydroxyl group of the galactosyl residue. The trisaccaride α-d-Galp-(1 → 6)-α-d-Galp-(1 → 6)-d-Glcp formed could be utilised by various intestinal bacteria, including various bifidobacteria, and might be an interesting pre- and synbiotic substrate. Received: 15 March 1999 / Received revision: 8 June 1999 / Accepted: 11 June 1999     

The structures of six urinary oligosaccharides that are characteristic for a patient with morquio syndrome type b

Morquio syndrome type B is an inherited, lysosomal storage disease characterised by a marked deficiency in acid β-d-galactosidase, while the 2-acetamido-2-deoxy-β-d-galactose 6-sulphate sulphatase activity is normal. Urinary oligosaccharides were studied in order to evaluate the effect of the diminished β-d-galactosidase activity on the catabolism of glycoconjugates and to compare their structures with those excreted by patients with GM₁-gangliosidosis. The following oligosaccharides were isolated: β-d-Galp-(1→4)-β-d-GlcpNAc-(1→2)-α-d-Manp-(1→6)-β-d-Manp-(1→4)- d-GlcpNAc (1), β-d-Galp-(1→4)-β-d-GlcpNAc-(1→2)-α-d-Manp-(1→6)-[α-d-Manp- (1→3)]-β-d-Manp-(1→4)-d-GlcpNAc (2a), β-d-Galp-(1→4)-β-d-GlcpNAc-(1→2)- α-d-Manp-(1→3)-[α-d-Manp-(1→6)]-β-d-Manp-(1→4)-d-GlcpNAc (2b), β-d-Galp- (1→4)-β-d-GlcpNAc-(1→2)-α-d-Manp-(1→3)-[β-d-Galp-(1→4)-β-d-GlcpNAc-(1→ 2)-α-d-Manp-(1→6)]-β-d-Manp-(1→4)-d-GlcpNAc (3), β-d-Galp-(1→4)-β-d-Glcp- NAc-(1→2)-α-d-Manp-(1→3)-{β-d-Galp-(1→4)-β-d-GlcpNAc-(1→2)-[β-d-Galp- (1→4)-β-d-GlcpNAc-(1→6)]-α-d-Manp-(1→6)}-β-d-Manp-(1→4)-d-GlcpNAc (4), β-d-Galp-(1→4)-β-d-GlcpNAc-(1→2)-α-d-Manp-(1→3)-[β-d-GlcpNAc-(1→4)]-[β- d-Galp-(1→4)-β-d-GlcpNAc-(1→2)-α-d-Manp-(1→6)]-β-d-Manp-(1→4)-d-Glcp- NAc (5). Significant differences between Morquio syndrome type B and GM₁-gangliosidosis have been observed, with regard to the excretion rate and the specific structures of urinary oligosaccharides. Compounds 2a, 2b, and 5 are novel members of the series of oligosaccharides isolated from the urine of patients with inherited, lysosomal storage diseases.     

Sequential solvent extraction and structural characterization of polysaccharides from the endosperm cell walls of barley grown in different environments

The objective of this study was to examine the composition and molecular structure of the endosperm cell walls (CW) derived from barley grain grown in three environments in Canada, and differing in grain hardness, protein, and total β-glucan contents. The endosperm CW were isolated from barley, cv. Metcalfe, grown in Davidson, SK (Sample A), Hythe, AB (sample B), and Hamiota, MB (sample C). The CW were sequentially extracted with water at 65 ^oC, saturated Ba(OH)₂, again with water at 25 ^oC, and 1 M NaOH, resulting in fractions designated WE65, BaE, Ba/WE, and NaE, respectively. The monosaccharide analysis indicated the presence of β-glucans, arabinoxylans, and small amounts of arabinogalactans, glucomannans, and xyloglucans. Cellulose was detected in the CW remnants. The CW of sample A, exhibiting a lower grain hardness than sample B, contained the lowest amount of β-glucans, but the highest amount of arabinoxylans and the mannose-containing polysaccharides. The CW of sample C, characterized by very high protein content in the grain, contained the highest amount of β-glucans and the lowest amount of other polysaccharides. Polysaccharides in the CW of sample B, exhibiting the highest grain hardness, were characterized by the highest weight average molecular weights (M_w). β-Glucans in the CW of Sample B showed the highest ratio of DP3/DP4 and the longest cellulosic fragments in the polymeric chains. Of the three barley samples, arabinoxylans in the endosperm CW of sample A exhibited the lowest degree of branching, the highest amount of unsubstituted Xyl residues, and the highest ratio of singly to doubly substituted Xylp. The highest water solubility of the CW of sample C was associated with the highest concentration of β-glucans, the lowest DP3/DP4 ratio, and the lowest M_w of the polymeric constituents. Arabinoxylans with the lowest amount of doubly substituted but the highest amount of unsubstituted xylose residues and long sequences of unsubstituted xylan regions were found in the NaE fractions. The NaE fractions showed a high ratio of →4)-Glcp-(1→ to →3)-Glcp-(1→ linkages and some →4)-Manp-(1→ linkages, indicating a high level of long cellulosic regions in β-glucan chains and the presence of glucomannans.     

Enzymatic synthesis of unique sialyloligosaccharides using marine bacterial α-(2→3)- and α-(2→6)-sialyltransferases

We investigated the acceptor substrate specificities of marine bacterial α-(2→3)-sialyltransferase cloned from Photobacterium sp. JT-ISH-224 and α-(2→6)-sialyltransferase cloned from Photobacterium damselae JT0160 using several saccharides as acceptor substrates. After purifying the enzymatic reaction products, we confirmed their structure by NMR spectroscopy. The α-(2→3)-sialyltransferase transferred N-acetylneuraminic acid (Neu5Ac) from cytidine 5′-monophospho-N-acetylneuraminic acid (CMP-Neu5Ac) to the β-anomeric hydroxyl groups of mannose (Man) and α-Manp-(1→6)-Manp, and α-(2→6)-sialyltransferase transferred N-acetylneuraminic acid to the 6-OH groups of the non-reducing end galactose residues in β-Galp-(1→3)-GlcpNAc and β-Galp-(1→6)-GlcpNAc.     

Xanthone O-glycosides from Polygala tenuifolia

Four xanthone O-glycosides, polygalaxanthones IV–VII were isolated from the roots of Polygala tenuifolia Willd., together with eight known compounds. The structures of the four xanthone O-glycosides were established as 6-O-[α- -rhamnopyranosyl-(1→2)-β- -glucopyranosyl]-1-hydroxy-3,7-dimethoxyxanthone (polygalaxanthone IV), 6-O-[α- -rhamnopyranosyl-(1→2)-β- -glucopyranosyl]-1,3-dihydroxy-7-methoxyxanthone (polygalaxanthone V), 6-O-(β- -glucopyranosyl)-1,2,3,7-tetramethoxyxanthone (polygalaxanthone VI), and 3-O-[α- -rhamnopyranosyl-(1→2)-β- -glucopyranosyl]-1,6-dihydroxy-2,7-dimethoxyxanthone (polygalaxanthone VII), respectively, on the basis of analysis of spectroscopic evidence.     

The Gentio-Oligosaccharide Gentiobiose Functions in the Modulation of Bud Dormancy in the Herbaceous Perennial Gentiana

Bud dormancy is an adaptive strategy that perennials use to survive unfavorable conditions. Gentians (Gentiana), popular alpine flowers and ornamentals, produce overwintering buds (OWBs) that can persist through the winter, but the mechanisms regulating dormancy are currently unclear. In this study, we conducted targeted metabolome analysis to obtain clues about the metabolic mechanisms involved in regulating OWB dormancy. Multivariate analysis of metabolite profiles revealed metabolite patterns characteristic of dormant states. The concentrations of gentiobiose [β-d-Glcp-(1→6)-d-Glc] and gentianose [β-d-Glcp-(1→6)-d-Glc-(1→2)-d-Fru] significantly varied depending on the stage of OWB dormancy, and the gentiobiose concentration increased prior to budbreak. Both activation of invertase and inactivation of β-glucosidase resulted in gentiobiose accumulation in ecodormant OWBs, suggesting that gentiobiose is seldom used as an energy source but is involved in signaling pathways. Furthermore, treatment with exogenous gentiobiose induced budbreak in OWBs cultured in vitro, with increased concentrations of sulfur-containing amino acids, GSH, and ascorbate (AsA), as well as increased expression levels of the corresponding genes. Inhibition of GSH synthesis suppressed gentiobiose-induced budbreak accompanied by decreases in GSH and AsA concentrations and redox status. These results indicate that gentiobiose, a rare disaccharide, acts as a signal for dormancy release of gentian OWBs through the AsA-GSH cycle.