Some structural features of an insoluble α-D-glucan from a mutant strain of Leuconostoc mesenteroides NRRL B-1355

Leuconostoc mesenteroides strain NRRL B-1355 produces two soluble extracellular α-D-glucans from sucrose: alternan and dextran. An unusual mutant strain derived from NRRL B-1355 has recently been isolated which produces practically no soluble polysaccharide, but significant amounts of an insoluble D-glucan. Methylation analysis shows it contains linear (1→3) and (1→6) linkages as well as (1→2) and (1→3) branch linkages. The insoluble glucan was partially digestible by endodextranase, giving rise to a series of oligosaccharides, a high-molecular weight soluble fraction and an insoluble residue. Treatment of the soluble dextranase-limit fraction with an α(1→2) debranching enzyme led to further dextranase susceptibility. Methylation, FTIR and NMR analyses of the dextranase-treated fractions indicate a non-uniform structure with domains bearing similarities to L. mesenteroides strain NRRL B-1299 dextran and to insoluble streptococcal D-glucans. Received 05 November 1998/ Accepted in revised form 31 March 1999     

Structural peculiarities of the O-specific polysaccharides of <Emphasis Type="Italic">Azospirillum</Emphasis> bacteria of serogroup III

Lipopolysaccharides and O-specific polysaccharides were isolated from the outer membrane of bacterial cells of three strains belonging to two Azospirillum species, and their structures were established by monosaccharide analysis including determination of the absolute configurations, methylation analysis, and one- and two-dimensional NMR spectroscopy. It was shown that while having the identical composition, the O-polysaccharides have different branched tetrasaccharide repeating units. Two neutral polysaccharides were found in the lipopolysaccharide of A. brasilense 54, and the structure for the predominant O-polysaccharide was determined. The structural data, together with results of serological studies, enabled assignment of strains examined to a novel serogroup, III. The chemical basis for the serological relatedness among the azospirilla of this serogroup is presumably the presence of a common →3)-α-L-Rhap-(1→2)-α-L-Rhap-(1→3)-α-L-Rhap-(1→oligosaccharide motif in their O-polysaccharides.     

Di-<Emphasis Type="Italic">tert</Emphasis>-butylsilylene-directed α-selective synthesis of <Emphasis Type="Italic">p</Emphasis>-nitrophenyl T-antigen analogues

Seven analogues of p-nitrophenyl T-antigen [Galβ(1→3)GalNAcα(1→O)PNP] have been synthesized as potential substrates for elucidation of the substrate specificity of endo-α-N-acetylgalactosaminidase. These compounds, which are commercially unavailable, include: GlcNAcβ(1→3){GlcNAcβ(1→6)}GalNAcα(1→O)PNP [core 4 type], GalNAcα(1→3)GalNAcα(1→O)PNP [core 5 type], GlcNAcβ(1→6)GalNAcα(1→O)PNP [core 6 type], GalNAcα(1→6)GalNAcα(1→O)PNP [core 7 type], Galα(1→3)GalNAcα(1→O)PNP [core 8 type], Glcβ(1→3)GalNAcα(1→O)PNP and GalNAcβ(1→3)GalNAcα(1→O)PNP. The assembly of these synthetic probes was accomplished efficiently, based on di-tert-butylsilylene(DTBS)-directed α-galactosylation as a key reaction.     

Characterization of the lipopolysaccharides from Rhizobium meliloti strain 102F51 and its nonnodulating mutant WL113

Lipopolysaccharides from the Rhizobium meliloti wild-type strain 102F51, which is effective in symbiosis with alfalfa, and from the nonnodulating mutant WL113, defective in root hair adhesion, derived thereof, were isolated and comparatively analyzed. Both preparations were composed of galactose, glucose, glucuronic acid, galacturonic acid, glucosamine, 3-deoxyheptulosaric acid, and 2-keto-3-deoxyoctonic acid as the major sugar constitutents. After a modified methylation analysis (consisting of the following consecutive steps: methylation, carboxyl reduction, remethylation, mild acid hydrolysis, reduction, and trideuterio-methylation), all of the 3-deoxyheptulosaric and some of the 2-keto-3-deoxyoctonic acid residues were converted into their corresponding 3-deoxyalditol derivatives, which carried trideuteriomethyl groups at positions C-2, C-4, and C-6. Another part of the permethylated 3-deoxyoctitol was also found as 2,5,6- and 2,6,8-tri-O-trideuteriomethyl derivatives. NMR data obtained with the separated oligosaccharides and the results of methylation analysis indicated that the majority of 2-keto-3-deoxyoctonate was present in the fraction of permethylated disaccharide alditols, namely as 6-O-CD₃-aGlc(1→5)3-deoxyoctitol, 6-O-CD₃-βGlcNMeAcyl(1→4)3-deoxyoctitol, and as the permethylated trisaccharide alditol, αGalA(1→3)-[6-O-CD₃]-β-Glc(1→5)-[4-O-CD₃]-3-deoxyoctitol. The presence of trideuteriomethyl groups at C-4 of both 3-deoxyalditols and at C-6 of the glucosaminyl or glucosyl residues indicated the linkage points of the released acid-labile ketosidic substituents, such as 3-deoxyheptulosarate and 2-keto-3-deoxyoctonate, in these oligosaccharides. The main differences between the preparations from the wild-type 102F51 and its mutant strain WL 113 were found in the higher content (in strain 102F51) of the following oligosaccharides: α-glucuronosyl(1→4)2-keto-3-deoxyoctonate and α-galacturonosyl-(1→3)α-glucosyl-(1→5)2-keto-3-deoxyoctonate and in the decreased content of β-glucosaminyl(1→4)2-keto-3-deoxy-octonate. Received: 21 July 1995 / Accepted: 25 October 1995     

Polysaccharide composition of mycelium and cell walls of the fungus <Emphasis Type="Italic">Penicillium roqueforti</Emphasis>

Preliminary data on the polysaccharide composition of mycelium and cell walls of the fungus Penicillium roqueforti grown by the method of submerged cultivation have been obtained. Mild acid hydrolysis of both mycelium and cell walls results in formation of glucose, mannose, and galactose, while the treatment with acid under severe conditions results in formation of glucosamine, a product of chitin hydrolysis, the content of which is 19% in the cell walls. Several polysaccharide fractions were isolated from mycelium by successive extraction with hot water and 1 M NaOH at room temperature; their monosaccharide composition was characterized. The main fraction extracted by alkali, according to the data of NMR spectroscopy, mass spectrometry, and the chemical methods of structural analysis, is a linear α-D-glucopyranan, where the blocks of (1 → 3)-bound glucose residues are linked by single bonds (1 → 4). Water-soluble polysaccharides contain the linear blocks of (1 → 5)-bound residues of β-galactofuranose, most probably attached to the mannan core. The findings are of interest for chemotaxonomy of Penicillium fungi.     

Structural and functional characterization of <Emphasis Type="Italic">Delphinus delphis</Emphasis> hemoglobin system

Structural analysis of the hemoglobin (Hb) system of Delphinus delphis revealed a high globin multiplicity: HPLC–electrospray ionization-mass spectrometry (ESI-MS) analysis evidenced three major β (β1 16,022 Da, β2 16,036 Da, β3 16,036 Da, labeled according to their progressive elution times) and two major α globins (α1 15,345 Da, α2 15,329 Da). ESI-tandem mass and nucleotide sequence analyses showed that β2 globin differs from β1 for the substitution Val126 → Leu, while β3 globin differs from β2 for the isobaric substitution Lys65 → Gln. The α2 globin differs from the α1 for the substitution Ser15 → Ala. Anion-exchange chromatography allowed the separation of two Hb fractions and HPLC–ESI-MS analysis revealed that the fraction with higher pI (HbI) contained β1, β2 and both the α globins, and the fraction with lower pI (HbII) contained β3 and both the α globins. Both D. delphis Hb fractions displayed a lower intrinsic oxygen affinity, a decreased effect of 2,3-BPG and a reduced cooperativity with respect to human HbA₀, with HbII showing the more pronounced differences. With respect to HbA₀, either the substitution Proβ5 → Gly or the Proβ5 → Ala is present in all the cetacean β globins sequenced so far, and it has been hypothesized that position 5 of β globins may have a role in the interaction with 2,3-BPG. Regarding the particularly lowered cooperativity of HbII, it is interesting to observe that the variant human HbA, characterized by the substitution Lysβ65 → Gln (HbJ-Cairo) has a decreased cooperativity with respect to HbA₀.     

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.     

Biosynthesis of yeast mannan. Characterization of mannan-synthesizing enzyme systems from mutants defective in mannan structure

The yeastSaccharomyces cerevisiae X2180-1A (wild) and its mutants X2180-1A-4 (mnn 1) and X2180-1A-5 (mnn 2) defective in mannan biosynthesis were used as enzyme sources to catalyzein vitro mannosyl transfer from GDP-[¹⁴C-U]-mannose to endogenous glycoproteins as well as to exogenous, low-molecular weight acceptors. While the enzyme preparation from the wild strain exhibited all mannosyl transferase activities involved in mannan biosynthesis by catalyzing the synthesis of characteristic mannoprotein, the enzyme frommnn 1 mutant failed to catalyze the synthesis of α(1→3) mannoside linkages both with endogenous as well as with exogenous acceptors. The enzyme preparation from themnn 2 mutant catalyzed the formation of mannoprotein very similar to that obtained with the enzyme from the wild strain. The most important difference was the formation of a higher number of unsubstituted mannosyl units in the α(1→ 6) linked mannan backbone. The observed results support the hypothesis that in themnn 1 the mutation has altered the structural gene involved in biosynthesis of an α(1→3) mannosyl transferase catalyzing the addition of α(1→3) linked mannosyl units to α(1→2) linked mannotrioses in the polysaccharide side chains and in the oligosaccharides attached to serine and/or threonine in the protein part of mannan molecule. Themnn 2 mutant represents most probably a kind of regulatory mutation where the activity of an α(1→2) mannosyl transferase adding the mannosyl units directly to α(1→6) linked backbone in the outer region of polysacoharide part of yeast mannan is repressedin vivo but becomes significantin vitro.     

MMC and LD simulations of α-D-Manp-(1→2)-β-D-Glcp-OMe: comparison to long-range heteronuclear NMR coupling constants and to the crystal structure

The conformational flexibility and the dynamics of -D-Manp-(12)--D-Glcp-OMe have been investigated by Metropolis Monte Carlo (MMC) and Langevin dynamics (LD) simulations. The two simulation techniques employ different force fields, namely the HSEA force field and a CHARMm-based force field. The former shows less conformational flexibility than the latter, in which a multiple energy minima conformational space is sampled. Long-range heteronuclear nuclear magnetic resonance (NMR) coupling constants have been measured by selective excitations of the carbons at the glycosidic linkage. Calculated 3JC, H values from MMC and LD simulations show excellent agreement to those from NMR experiments. The X-ray crystal structure has a conformation within a region of the conformational space populated in both force fields.     

Characterization of the <Emphasis Type="Italic">Pragia fontium</Emphasis> Lipopolysaccharides

Lipopolysaccharides (LPSs) of two strains Pragia fontium 97U116 and 27480 were isolated and characterized; they were close to those of other representatives of the family Enterobacteriaceae in fatty acid composition and contained, respectively, 3-hydroxytetradecanoic acid as the predominant component (45.8 and 45.1%), tetradecanoic (23.5 and 28.9%), hexadecanoic (12.6 and 7.9%), hexadecenoic (12.6 and 7.9%), and dodecanoic (4.9 and 4.2%) fatty acids. The O-specific polysaccharides consisted of linear penta- and tetrasaccharide repeating units: →2)-α-D-Galf-(1→3)-α-L-Rhap2Ac-(1→4)-α-D-GlcpNAc-(1→2)-α-L-Rhap-(1→3)-β-D-GlcpNAc-(1→ →4)-β-D-ManpNAc3NAcA-(1→2)-α-L-Rhap-(1→3)-β-L-Rhap-(1→4)-α-D-GlcpNAc-(1→ The LPSs of P. fontium 97U116 and 27480 were serologically active and belonged to different serogroups; they were less toxic than those of strain E. coli O55:B5, but more pyrogenic than the Pyrogenal preparation.     

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     

Immunization of mice with fucosyl-GM1 conjugated with keyhole limpet hemocyanin results in antibodies against human small-cell lung cancer cells

Fucosyl-GM1 (Fuc-GM1) [Fucα1 → 2Galβ1 → 3GalNAcβ1 → 4(NeuAcα2-3)Galβ1 → 4Glcβ1 → O-Cer] is a small-cell-lung-cancer (SCLC)-associated ganglioside initially defined by the murine monoclonal antibody F12. On the basis of its known distribution, Fuc-GM1 is a potential target for active immunotherapy in SCLC patients. Fuc-GM1 has been extracted and purified from bovine thyroid. The immunogenicity of Fuc-GM1 was tested in mice either alone, mixed with carrier protein keyhole limpet hemocyanin (KLH) or covalently linked with KLH, plus immunological adjuvant QS-21. The Fuc-GM1-KLH conjugate plus QS-21 adjuvant was found to be optimal. It induced consistent IgM and IgG enzyme-linked immunosorbent assay (ELISA) titers against Fuc-GM1. These antibodies were strongly reactive with the strongly Fuc-GM1-positive rat hepatoma cell line H4-II-E, and they were moderately reactive with the moderately positive human SCLC cell line H146 by flow cytometry and complement-mediated lysis. Both ELISA and fluorescence-activated cell sorting (FACS) reactions were inhibited with Fuc-GM1or H4-II-E but not with the structurally related ganglioside GM1 or Fuc-GM1-negative colon cancer cell line LS-C. On the basis of these results, a vaccine comprising Fuc-GM1-KLH plus QS-21 is being prepared for testing in patients with SCLC. Received: 25 March 1999 / Accepted: 5 August 1999     

O-polysaccharide structure in serogroup I azospirilla

Lipopolysaccharides (LPS) and O-specific polysaccharides (OPS) were obtained from the outer membrane of four Azospirillum strains previously assigned to serogroup I based on the serological affinity revealed by the antibodies (AB) to the LPS of A. brasilense Sp245. Investigation, including determination of monosaccharide composition, methylation analysis, and one- and two-dimensional NMR spectroscopy, was carried out to determine the OPS structure. The OPSs of A. brasilense Sp107 and S27 and of A. lipoferum RG20a were found to have an identical structure of repeating units represented by a linear penta-D-rhamnan, as was previously described for the OPSs of A. brasilense Sp245 and SR75. The OPS of A. brasilense SR15 was found to consist of tetrasaccharide repeating units of the following structure: → 2)-α-D-Rhap-(1 → 2)-β-D-Rhap-(1 → 3)-α-D-Rhap-(1 → 2)-α-D-Rhap-(1 →. An opine compound, N^δ-(1-carboxyethyl)-ornithine, closely associated with the LPS of A. brasilense SR15, was identified in azospirilla for the first time. The presence of a 6-deoxisugar (D-rhamnose) in the OPS structure was shown to be the chemical basis of the serological similarity and the reason for classification of these strains within the serogroup I.     

Design and efficient synthesis of novel GM2 analogues with respect to the elucidation of the function of GM2 activator

To elucidate the mechanism underlying the hydrolysis of the GalNAcβ1→4Gal linkage in ganglioside GM2 [GalNAcβ1→4(NeuAcα2→3)Galβ1→4Glcβ1→1′ Cer] by β-hexosaminidase A (Hex A) with GM2 activator protein, we designed and synthesized two kinds of GM2 linkage analogues—6′-NeuAc-GM2 and α-GalNAc-GM2. In this paper, the efficient and systematic synthesis of these GM2 analogues was described. The highlight of our synthesis process is that the key intermediates, newly developed sialyllactose derivatives, were efficiently prepared in sufficient quantities; these derivatives directly served as highly reactive glycosyl acceptors and coupled with GalNTroc donors to furnish the assembly of GM2 tetrasaccharides in large quantities.     

The structure of sulfated cauloside C

The structure of the sulfated analogue of cauloside C, a biologically active triterpenoid glycoside, was elucidated to be 3-O-[β-D-glucopyranosyl-(1→2)-α-L-arabinopyranosyl]-hederagenin 23,4′,4″,6″-tetrasulfate pentasodium salt by the comparison of its¹³C NMR spectrum with that of cauloside C potassium salt.     

Note: Characterisation of furcellaran samples from Estonian <Emphasis Type="Italic">Furcellaria lumbricalis</Emphasis> (Rhodophyta)

The structure of furcellarans obtained from red algae Furcellaria lumbricalis collected in Estonia was determined. Native and alkali-modified furcellarans were examined by gas chromatography/mass spectrometry (GC/MS), and ¹³C-nuclear magnetic resonance spectroscopy (NMR) and were compared with commercial furcellaran (FMC Food Ingredients). The polysaccharide preparation consisted mainly of (1→3) linked β-D-galactopyranose, (1→4) linked 3,6-anhydro-α-D-galactopyranose and (1→3) linked β-D-galactopyranose 4-sulphate. Alkaline treatment removed the sulphate precursor sequences with formation of 3,6-anhydrogalactose that improved the furcellaran gelling ability.     

Low-Molecular-Weight Compounds

Self-association of caffeine has been investigated using mass spectrometry. It was found that associates are composed of caffeine trimers and hexamers. The possibility of complex formation of caffeine with triterpene glycosides 3-O-α-L-rhamnopyranosyl-(1→2)-O-α-L-arabinopyranoside of hederagenin and its 28-O-α-L-rhamnopyranosyl-(1→4)-O-β-D-glucopyranosil-(1→6)-O-β-D-glucopyranosil ester have been considered. Under the experimental conditions, inclusion compounds do not form and only self-associates of caffeine and glycosides are found.     

Structure of the O-Specific polysaccharide from Shewanella japonica KMM 3601 containing 5,7-Diacetamido-3,5,7,9-tetradeoxy-D-glycero-D-talo-non-2-ulosonic acid

Structure of the O-specific polysaccharide chain of the lipopolysaccharide (LPS) of Shewanella japonica KMM 3601 was elucidated. The initial and O-deacylated LPS as well as a trisaccharide representing the O-deacetylated repeating unit of the O-specific polysaccharide were studied by sugar analysis along with ¹H and ¹³C NMR spectroscopy. The polysaccharide was found to contain a rare higher sugar, 5,7-diacetamido-3,5,7,9-tetradeoxy-d-glycero-d-talo-non-2-ulosonic acid (a derivative of 4-epilegionaminic acid, 4eLeg). The following structure of the trisaccharide repeating unit was established: →4)-α-4eLegp5Ac7Ac-(2→4)-β-d-GlcpA3Ac-(1→3)-β-d-GalpNAc-(1→.     

A comparative study of specificity of fucoidanases from marine microorganisms and invertebrates

Specificities of actions of fucoidanases from the marine microorganism Pseudoalteromonas citrea KMM 3296 and the marine mollusk Littorina kurila were studied. The enzymes possess similar specificities and catalyze the cleavage of accessible α-(1→3)-fucoside bonds in fucoidans with highly sulfated α-(1→4; 1→3)-L-fucooligosaccharides. A high degree of sulfation of the fucose residues in fucoidans makes α-(1→3)-L-fucoside bonds inaccessible for the action of the studied enzymes. The maximum degree of cleavage of fucoidan was achieved by the fucoidanase from the marine bacterium Pseudoalteromonas citrea KMM 3296.     

DNA Polymerase-associated and autonomous vertebrate 3′→5′ exonuleases

Using methods of gel filtration and ultracentrifugation, cell-free extracts from 12 objects representing the main vertebrate representatives (bony fish, amphibian, reptiles, birds, mammals, including human) were studied. The enzyme activity of autonomous 3′→5′-exonucleases (AE) has been established to be 25–90% of the total 3′→5′ exonuclease activity of the extracts. A part of the AE is revealed in a zone of the DNA polymerases of the α-family and can be separated by changing Chromatographic conditions or by repeated fractionation. The high activity of AE allows suggesting their substantial participation in the replicative correction of the DNA-poly-merase errors as well as in the postreplicative correction of the heteroduplexes in the vertebrate DNA.