The behavior of cellulose,amylose, and β-d-xylan towards anhydrous hydrogen fluoride

Cellulose, amylose, and d-glucose are converted into α-d-glucopyranosyl fluoride (3) when dissolved in anhydrous hydrogen fluoride. The fluoride subsequently undergoes condensation to afford a mixture of ligosaccharides, probably via an oxocarbonium ion. The fluoride 3 and the oligosaccharides are in an equilibrium, which was studied by ¹³C-n.m.r. spectroscopy; in dilute solution in hydrogen fluoride, the d-glucosyl fluoride is the main product present, but when the hydrogen fluoride is evaporated, the equilibrium is shifted towards the oligosaccharides. These constitute a complex mixture which was studied by methylation and subsequent analysis of the methylated alditols derived therefrom. (1→4)-β-d-Xylan and d-xylose behave similarly to the d-glucose derivatives towards hydrogen fluoride.     

Synthesis of (S)-2-fluoro- -daunosamine and (S)-2-fluoro- -ristosamine

Derivatives of (S)-2-fluoro- -daunosamine and (S)-2-fluoro- -ristosamine were synthesized, starting ultimately from 2-amino-2-deoxy- -glucose which was converted, according to the literature, into methyl 2-benzamido-4,6-O-benzylidene-2-deoxy-3-O-(methylsulfonyl)-α- -glucopyranoside (2). Treatment of 2 with tetrabutylammonium fluoride gave a 63% yield of (known) methyl 3-benzamido-4,6-O-benzylidene-2,3-dideoxy-2-fluoro-α- -altropyranoside (4), together with a 6% yield of its 2-benzamido-2,3-dideoxy-3-fluoro-α- -gluco isomer. From 4, the corresponding 6-bromo-2,3,6-trideoxyglycoside 4-benzoate (6) was obtained by Hanessian-Hullar reaction. Dehydrobromination of 6, followed by catalytic hydrogenation of the resulting 5-enoside, and subsequent debenzoylation and N-trifluoroacetylation, afforded the fluorodaunosaminide, methyl 2,3,6-trideoxy-2-fluoro-3-trifluoroacetamido-β- -galactopyranoside. Reductive debromination of 6, followed by debenzoylation and N-trifluoroacetylation, gave the fluororistosaminide, methyl 2,3,6-trideoxy-2-fluoro-3-trifluoroacetamido-α- -altropyranoside. The ¹H-n.m.r. spectra of the new aminofluoro sugars are discussed with respect to the effects of neighboring amino and acylamido substituents on geminal and vicinal ¹H–¹⁹F coupling constants, in comparison with the reported effects of oxyge substituents.     

The stereochemical course of the reaction mechanism of trehalose phosphorylase from Schizophyllum commune

Phosphorolysis of α,α-trehalose catalyzed by trehalose phosphorylase from the basidiomycete Schizophyllum commune proceeds via net retention of anomeric configuration and yields α- -glucose 1-phosphate and α- -glucose as the products. In reverse reaction, only the α-anomers of -glucose 1-phosphate and -glucose are utilized as glucosyl donor and acceptor, respectively, and give exclusively the α,α-product. Trehalose phosphorylase converts α- -glucose 1-fluoride and phosphate into α- -glucose 1-phosphate, a reaction requiring the stereospecific protonation of the glucosyl fluoride by a Brønsted acid. The results are discussed with regard to a plausible reaction mechanism of fungal trehalose phosphorylase.     

Chemical characterization of sialyl oligosaccharides in milk of the Japanese black bear, Ursus thibetanus japonicus

Sialyl oligosaccharides were separated from two samples of Japanese black bear milk by extraction with chloroform/methanol, gel filtration on Bio Gel P-2, ion exchange chromatography on DEAE-Sephadex A-50 and high-performance liquid chromatography (HPLC) on a TSK gel Amido-80 column. They were characterized by ¹H-NMR spectroscopy. The structures of four sialyl oligosaccharides separated from the milk were the following:

Neu5Ac(α2-3)Gal(β1-4)Glc

Neu5Ac(α2-6)Gal(β1-4)GlcNAc(β1-3) Gal(α1-3)Gal(β1-4)[Fuc(α1-3)]GlcNAc(β1-6) Gal(β1-4)Glc

Neu5Ac(α2-6)Gal(β1-4)GlcNAc(β1-3) Gal(α1-3)[Fuc(α1-2)]Gal(β1-4)[Fuc(α1-3)]GlcNAc(β1-6) Gal(β1-4)Glc

Neu5Ac(α2-6)Gal(β1-4)GlcNAc(β1-3)[Neu5Ac(α2-6)Gal(β1-4)GlcNAc(β1-6)]Gal(β1-4)Glc

Synthesis of methyl O-(3-deoxy-3-fluoro-β- -galactopyranosyl)-(1→6)-β- -galactopyranoside and methyl O-(3-deoxy-3-fluoro-β- -galactopyranosyl)-(1→6)-O-β- -galactopyranosyl-(1→6)-β- -galactopyranoside

Condensation of 2,4,6-tri-O-acetyl-3-deoxy-3-fluoro-α- -galactopyranosyl bromide (3) with methyl 2,3,4-tri-O-acetyl-β- -galactopyranoside (4) gave a fully acetylated (1→6)-β- -galactobiose fluorinated at the 3′-position which was deacetylated to give the title disaccharide. The corresponding trisaccharide was obtained by reaction of 4 with 2,3,4-tri-O-acetyl-6-O-chloroacetyl-α- -galactopyranosyl bromide (5), dechloroacetylation of the formed methyl O-(2,3,4-tri-O-acetyl-6-O-chloroacetyl-β- -galactopyranosyl)-(1→6)- 2,3,4-tri-O-acetyl-β- -galactopyranoside to give methyl O-(2,3,4-tri-O-acetyl-β- -galactopyranosyl)-(1→6)-2,3,4-tri-O-acetyl-β- -galactopyranoside (14), condensation with 3, and deacetylation. Dechloroacetylation of methyl O-(2,3,4-tri-O-acetyl-6-O-chloroacetyl-β- -galactopyranosyl)-(1→6)-O-(2,3,4-tri-O-acetyl- β- -galactopyranosyl)-(1→6)-2,3,4-tri-O-acetyl-β- -galactopyranoside, obtained by condensation of disaccharide 14 with bromide 5, was accompanied by extensive acetyl migration giving a mixture of products. These were deacetylated to give, crystalline for the first time, the methyl β-glycoside of (1→6)-β- -galactotriose in high yield. The structures of the target compounds were confirmed by 500-MHz, 2D, ¹H- and conventional ¹³C- and ¹⁹F-n.m.r. spectroscopy.     

Synthesis, and carbon-13 n.m.r. study, of O-α- -rhamnopyranosyl-(1→3)-O-α- -rhamnopyranosyl-(1→2)- -rhamnopyranose and O-α- -rhamnopyranosyl-(1→3)-O-α- -rhamnopyranosyl (1→3)- -rhamnopyranose, constituents of bacterial, cell-wall polysaccharides

O-α- -Rhamnopyranosyl-(1→3)- -rhamnopyranose (19) and O-α- -rhamnopyranosyl-(1→2)- -rhamnopyranose were obtained by reaction of benzyl 2,4- (7) and 3,4-di-O-benzyl-α- -rhamnopyranoside (8) with 2,3,4-tri-O-acetyl-α- -rhamnopyranosyl bromide, followed by deprotection. The per-O-acetyl α-bromide (18) of 19 yielded, by reaction with 8 and 7, the protected derivatives of the title trisaccharides (25 and 23, respectively), from which 25 and 23 were obtained by Zemplén deacetylation and catalytic hydrogenolysis, With benzyl 2,3,4-tri-O-benzyl-β- -galactopyranoside, compound 18 gave an ≈3:2 mixture of benzyl 2,3,4-tri-O-benzyl-6-O-[2,4-di-O-acetyl-3-O-(2,3,4-tri-O-acetyl-α- -rhamnopyranosyl)-α- -rhamnopyranosyl]-β- -galactopyranoside and 4-O-acetyl-3-O-(2,3,4-tri-O-acetyl-α- -rhamnopyranosyl)-β- -rhamnopyranose 1,2-(1,2,3,4-tetra-O-benzyl-β- -galactopyranose-6-yl (orthoacetate). The downfield shift at the α-carbon atom induced by α- -rhamnopyranosylation at HO-2 or -3 of a free α- -rhamnopyranose is 7.4-8.2 p.p.m., ≈1 p.p.m. higher than when the (reducing-end) rhamnose residue is benzyl-protected (6.6-6.9 p.p.m.). α- -Rhamnopyranosylation of HO-6 of gb- -galactopyranose deshields the C-6 atom by 5.7 p.p.m. The 1 2-orthoester ring structure [O₂,C(me)OR] gives characteristic resonances at 24.5 ±0.2 p.p.m. for the methyl, and at 124.0 ±0.5 p.p.m. for the quaternary, carbon atom.     

Single-crystal and powder X-ray diffraction and solid-state C NMR of p-nitrophenyl glycopyranosides, the derivatives of d-galactose, d-glucose, and d-mannose

The X-ray diffraction patterns, ¹³C CP MAS NMR spectra, and powder X-ray diffraction analyses were obtained for selected p-nitrophenyl glycosides: α- and β-d-galactopyranosides (1 and 2), α- and β-d-glucopyranosides (3 and 4), and α- and β-d-mannopyranosides (5 and 6). In X-ray diffraction analysis of 1 and 2, characteristic shortening and lengthening of selected bonds were observed in the molecules of 1 due to anomeric effect, and in the crystal lattice of 1 and 2, hydrogen bonds of complex network were detected. In the crystal asymmetric unit of 1 there were two independent molecules, whereas in 2 there was one molecule. For 1 and 3–6 the number of resonances in solid-state ¹³C NMR spectra exceeded the number of the carbon atoms in the molecules, while for 2 there were distinct singlet resonances in its solid-state NMR spectrum. Furthermore, the powder X-ray diffraction (PXRD) performed for 1–3 and 5 revealed that 1, 3, and 5 existed as single polymorphs proving that the doublets observed in appropriate solid-state NMR spectra were connected with two non-equivalent molecules in the crystal asymmetric unit. On the other hand 2 existed as a mixture of two polymorphs, one of them was almost in agreement with the calculated pattern obtained from XRD (the difference in volumes of the unit cells), and the subsequent unknown polymorph existed in small amounts and therefore it was not observed in solid-state NMR measurements.     

Structural analysis of two 2-deoxy analogues of α- and β-KDO and the methyl α- and β-glycosides of KDO, and determination of their metal-ion-binding properties

Ammonium 2,6-anhydro-3-deoy- -glycero- -talo-octonate (1), a potent inhibitor of the enzyme CMP-KDO synthetase, its C-2 epimer 2, and the methyl β-(3) and α-glycoside (4) of KDO were studied by ¹H- and ¹³C-n.m.r. spectroscopy. Compound 1 was also analysed by X-ray crystallography. Each compound adopted a ⁵C₂ chair conformation with the side chain equatorial. The preponderant side-chain conformation of 1 in solution was the same as that in the crystal and was stabilised by an intramolecular hydrogen bond from HO-8 to the carboxylate group. This hydrogen bond appeared to be present also in 3. However, the side-chain conformation of 2 and 4 was different from that in 1 and 3. The metal-ion-binding properties, determined on the basis of the line-broadening effects of Mn²⁺ on the ¹³C-n.m.r. signals, showed that the carboxylate group was involved in the binding with O-8 in 1 and 3 and with O-6 and O-8 in 2 and 4.     

Deoxyfluoroketohexoses: 4-deoxy-4-fluoro- -sorbose and -tagatose and 5-deoxy-5-fluoro- -sorbose

4-Deoxy-4-fluoro-α- -sorbose (6) was prepared in crystalline form by the action of potassium hydrogen fluoride on 3,4-anhydro-1,2-O-isopropylidene-β- -psicopyranose (3) followed by deacetonation. Under identical conditions 3,4-anhydro-1,2-O-isopropylidene-β- -tagatopyranose (7) underwent epoxide migration to give 4,5-anhydro- 1,2-O-isopropylidene-β- -fructopyranose (12), which after deacetonation yielded 4-deoxy-4-fluoro- -tagatose (15) 5-deoxy-5-fluoro-α- -sorbopyranose (16) the latter as the crystalline free sugar. The action of glycol-cleavage reagents on the isopropylidene acetals of the deoxyfluoro sugars was consistent with the assigned structures. The structures were established by ¹³C n.m.r. studies of the free deoxyfluoro sugars 6 and 16 of the isopropylidene acetal 13, and by ¹H n.m.r. studies on the acetylated isopropylidene acetals 5 diacetate, 13 diacetate, and 14 diacetate. 5-Deoxy-5-fluoro- -sorbose (16) was biologically active producing in mice effects characteristic of deoxyfluorotrioses and of fluoroacetate. 4-Deoxy-4-fluoro- -tagatose (15) and 4-deoxy-4-fluoro- -sorbose (6) produced no apparent effects in mice up to a dose of 500 mg/kg. The implications of these findings with respect to transport phosphorylation, and the action of aldolase on ketohexoses are discussed.     

Metabolism of the reserve polysaccharide of Streptococcus mitis. Properties of alpha-(1-->6)-glucosidase, its separation from transglucosylase, and the action of the two enzymes on branched oligosaccharides

1. An α-(1→6)-glucosidase has been separated from cell extracts of Streptococcus mitis. The enzyme was freed from transglucosylase by adsorption of the latter on retrograded amylose. 2. The enzyme was detected in five of the six strains of S. mitis that were studied; α-(1→6)-glucosidase was not found in strain RB1633, a strain that did not store polysaccharide. 3. The glucosidase could act on compounds in which α-glucose is joined through an α-(1→6)-bond to either a maltosaccharide or an isomaltosaccharide. 6²-α-Glucosylmaltose (panose) and 6³-α-glucosylmaltotriose were hydrolysed more rapidly and isomaltodextrins more slowly than isomaltose. 4. Transferring activity towards isomaltose and panose was appreciable when the concentration of substrate was 2% or higher. 5. The enzyme had no action on α-(1→4)-glucosidic linkages. 6-α-Maltodextrinylglucoses were hydrolysed only after transglucosylase action had attenuated them to isomaltose.     

The synthesis of P-(2-acetamido-2-deoxy-α-D-glucopyranosyl) P-ficaprenyl pyrophosphate

2-Acetamido-3,4,6-tri-O-acetyl-2-deoxy-α,β-D-glucopyranosylammonium phosphate was prepared by the action of crystalline phosphoric acid on 2-acetamido-1,3,4,6-tetra-O-acetyl-β-D-glucopyranose. The α-D anomer (3) was the main product, and was isolated pure by preparative thin-layer chromatography or by removal of the β-D anomer (6) by selective acid hydrolysis. Ficaprenyl phosphate was prepared from ficaprenol, obtained as an isomeric mixture (mainly C₅₅) from an extract of Ficus elastica. Compound 3 was converted into the free acid and then into the tributyl-ammonium salt, which was treated with P¹-diphenyl P²-ficaprenyl pyrophosphate to give the acetylated pyrophosphate diester 8, characterized by analytical, spectral, and hydrogenolytic studies. Deacetylation of 8 gave the synthetic “lipid intermediate”, P¹-(2-acetamido-2-deoxy-D-glucopyranosyl) P²-ficaprenyl pyrophosphate (9), the properties of which were compared with those of natural substances considered to be active in the biosynthesis of teichoic acids.     

Synthesis and evaluation of affinity adsorbents for glycoproteins: an artificial lectin

A combination of rational design based on mimicking natural protein–carbohydrate interactions and solid-phase combinatorial chemistry has led to the identification of an affinity ligand which displays selectivity for the mannose moiety of glycoproteins. The ligand, denoted 18/18 and comprising a triazine scaffold bis-substituted with 5-aminoindan, has been synthesised in solution, characterised by TLC, ¹H-NMR and MS. When immobilised to amine-derivatised agarose at concentrations >24 μmol/g moist weight gel, ligand 18/18 selectively binds glucose oxidase. The adsorbed enzyme was quantitatively eluted with 0.5 M α- -methyl-mannoside and to a lesser extent with the equivalent glucoside. An investigation of the comparative retention times of saccharidic solutes showed that significant retardation was observed for α- -mannose, mannobiose and mannan, with little or no evidence for selective retention of other saccharides, with the exception of α- -fucose. Interestingly, α- -fucose and α- -mannose share an identical configuration of the hydroxyl groups on C-2, C-3 and C-4. Analysis of Scatchard plots from partition equilibrium studies on the interaction of glucose oxidase and the p-nitrophenyl-glycosides of -mannose, -glucose, -fucose and -galactose with immobilised 18/18 establish that the affinity constants (K_AX) for the enzyme, the glycosides of mannose, glucose and fucose, and the p-nitrophenyl-galactoside are 4.3×10⁵ M⁻¹, 1.9×10⁴ M⁻¹ and 1.2×10⁴ M⁻¹ respectively. ¹H-NMR studies on the interaction of α- -methyl-mannoside with ligand 18/18 in solution confirm the involvement of the hydroxyl group in the C-2 position. Molecular modelling suggests the formation of four hydrogen bonds between the hydroxyl groups at positions C-2, C-3 and C-4 of α- -methyl-mannoside and the bridging and ring nitrogen atoms of the triazine scaffold, with aromatic stacking of a second ligand against the carbohydrate face. The greater specificity of ligand 18/18 for mannose and glucose than for galactose parallels that exhibited by concanavalin A.     

A study of the reactivity and structure of cyclic α,β-unsaturated Fischer-type carbene complexes

Cycloaddition reactions with α,β-unsaturated carbene complexes of the Fischer-type bearing the carbene carbon atom and the double bond incorporated in the same ring are described. Pentacarbonyl(2H-benzopyran-2- ylidene)chromium(0) complexes (2a-c) and pentacarbonyl(4-methoxy-3,3-dimethyl-2-oxacyclopentylidene)- chromium(0) (3) show a rather low reactivity towards 1,3-dipoles and 1,3-dienes. The reactions with diazomethane are regioselective but not chemoselective; compounds 2 and 3 show two sites of attack: the α,β carbon-carbon and the carbon-metal double bond. The crystal and molecular structures of 2a and 3 have been elucidated by single crystal X-ray analysis. Crystals of 2a are monoclinic, space group P2₁/c, a=7.614(3), b=14.033(3), c=12.766(3) Å, β=95.24°, V=1358.3(7) Å Z=4; crystals of 3 are triclinic, space group P , a=6.553(1), b=9.408(1), c=10.620(1) Å α=92.70(1), β=92.30(1), γ=92.12(1)°, V=653.0(1), ų, Z=2. Final agreement indices for 2a and 3 are R=0.034 and 0.033, respectively. Vibrational properties of the Cr(CO)₅ moiety were interpreted by FT-IR and FT-Raman spectroscopy. Electronic spectra and π electron distribution were interpreted by resonance Raman spectroscopy.     

Synthesis of methyl O-(3-deoxy-3-fluoro-β- -galactopyranosyl)-(1→6)-O-β- -galactopyranosyl-(1→6)-3-deoxy-3-fluoro -β- -galactopyranoside and related n.m.r. studies

Sequential tritylation, benzoylation, and detritylation of methyl 3-deoxy-3-fluoro-β- -galactopyranoside gave crystalline methyl 2,4-di-O-benzoyl-3-deoxy-3-fluoro-β- -galactopyranoside (9), which was used as the initial nucleophile in the synthesis of the target oligosaccharide (16). Treatment of 9 with 2,3,4-tri-O-benzoyl-6-O-bromoacetyl-α- -galactopyranosyl bromide gave the corresponding disaccharide derivative 13, having a selectively removable blocking group at O-6′. Debromoacetylation of 13 afforded the disaccharide nucleophile 14 which, when treated with 2,4,6-tri-O-benzoyl-3-deoxy-3-fluoro-α- -galactopyranosyl bromide, gave the fully protected trisaccharide 15. Debenzoylation of 15 gave the title glycoside 16. Condensation reactions were performed with silver trifluoromethane-sulfonate as a promoter in the presence of sym-collidine under base-deficient conditions, and gave excellent yields of the desired β-(trans)-products. Analyses of the ¹H- and ¹³C-n.m.r. spectra, as well as determination of the J_CF and J_HF coupling constants, were made by using various one- and two-dimensional n.m.r. techniques.     

Structure of the oligosaccharides isolated from Dalbergia sissoo Roxb. leaf polysaccharide

A water-soluble polysaccharide isolated from Dalbergia sissoo Roxb. leaves was purified and major homogeneous fraction obtained by GPC. Complete hydrolysis of the polysaccharide followed by paper chromatography and GLC analysis indicated the presence of l-rhamnose, d-glucuronic acid, d-galactose and d-glucose in molar ratio of 1:1:2:2.33, respectively. Partial hydrolysis of the polysaccharide furnished one tri-[I], one hepta-[II] and one nona-[III] saccharides. Hydrolysis of the oligosaccharide I, II and III followed by GLC analysis furnished d-glucose and l-rhamnose (2:1); l-rhamnose, d-galactose and d-glucuronic acid (1:3:3); and l-rhamnose, d-galactose and d-glucose (1:3:5), respectively. Methylation analysis and periodate oxidation of the oligosaccharide I indicated the presence of two non reducing glucose units linked to rhamnose by 1→2 and 1→4 linkages, respectively. Oligosaccharide II is a branched molecule with a main chain consisting of 1,3-linked β-d-galactopyranosyl (2 mol), 1,3,4 linked α-l-rhamnopyranosyl (1 mol) and 1,4,6 linked β-d-galactopyranosyl unit (1 mol) and non reducing β-d-glucuronic acid at the end along with side chains of β-d-glucouronopyranosyl units (2 mol). Oligosaccharide III is also a branched molecule with a main chain consisting of 1,3,4 linked α-l-rhamnopyranosyl (1 mol), 1,2,4 linked β-d-glucopyranosyl (1 mol), 1,3 and 1,4 linked β-d-galactopyranosyl (2 and 1 mol, respectively) having β-d-glucopyranosyl as a non reducing end.     

Conversion of amylose into a (1→4)-2-amino-2-deoxy-α-D-glucopyranuronan and its 2-N-sulfo derivative, a heparin analog

By a modification of a previously established reaction-sequence involving successive oxidation with methyl sulfoxide-acetic anhydride, oximation, and reduction with lithium aluminum hydride, 6-O-tritylamylose (1) was converted into a 6-O-tritylated (1→4)-α-D-linked glucan (3) containing 2-amino-2-deoxy-D-glucose residues and some O-(methylthio)methyl groups. Removal of the ether groups from this product gave a 2-aminated amylose (4) of degree of substitution (d.s.) by amine of 0.54 that underwent cleavage by fungal alpha-amylase to give oligosaccharides containing amino sugar residues. N-Trifluoroacetylation of 3 followed by removal of the ether groups, oxidation at C-6 with oxygen-platinum, and removal of the N-substituent, gave a (1 →4)-2-amino-2-deoxy-α-D-glucopyranuronan 7 having d.s. by amine of up to 0.65, and by carboxyl, of 0.46. Sulfation of this product with sulfur trioxide-pyridine and then with chlorosulfonic acid-pyridine gave a (1→4)-2-deoxy-2-sulfoamino-α-D-glucopyranuronan, isolated as its sodium salt 8, which showed appreciable blood-anticoagulant activity.     

Sequential synthesis and C-N.m.r. spectra of methyl β-glycosides of (1→4)-β-d-xylo-oligosaccharides

The reaction of 2,3-di-O-acetyl-4-O-benzyl-α,β-d-xylopyranosyl bromide (2) with methyl 2,3-di-O-acetyl-β-d-xylopyranoside gave methyl O-(2,3-di-O-acetyl-4-O-benzyl-β-d-xylopyranosyl)-(1→4)-2,3-di-O-acetyl-β-d-xylopyranoside (22). Catalytic hydrogenolysis of 22 exposed HO-4′ which was then condensed with 2. This sequence of reactions was repeated three more times to afford, after complete removal of protecting groups, a homologous series of methyl β-glycosides of (1→4)-β-d-xylo-oligosaccharides. ¹³C-N.m.r. spectra of the synthetic methyl β-glycosides (di- to hexa-saccharide) are presented together with data for six other, variously substituted, homologous series of (1→4)-d-xylo-oligosaccharides.     

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.     

The free reducing oligosaccharides of angico branco (Anadenanthera colubrina) gum exudate: an aid for structural assignments in the heteropolysaccharide

A novel method is described for the determination of sequential side-chain structures in the complex, high-arabinose polysaccharide of the gum exudate of angico branco (Anadenanthera colubrina), using as basis the structurally similar reducing oligosaccharides present in small quantities. Of the ten detected, eight were characterized as disaccharides (2, 3, and 9), linear trisaccharides (1 and 4), branched pentasaccharides (5 and 6), and a doubly branched heptasaccharide (8). The oligosaccharides are substituents of the polysaccharide, which has a (1→3)-linked β- -galactopyranosyl main chain, and with two exceptions they had 6-O-substituted galactopyranosyl reducing ends, probably corresponding to its main-chain units. Characterization was effected through their 1D and 2D NMR correlation spectra, which were better resolved and more readily interpretable than those of the polysaccharide. These spectral data were supported by monosaccharide composition and rotation values. Controlled Smith degradations and methylation analyses were carried out when it was necessary. These data were confirmed by field-desorption MS.     

Rhodium aryloxide complexes containing terdentate nitrogen ligands, C-O bond formation, hydrogen bonding with phenol and oxidative addition reactions. Molecular structure of an Rh(III)-acetyl complex

The new rhodium(I) phenoxide complexes [Rh(OPh) (2,6-(CH=R²)₂C₅H₃N)] (R² = i-Pr(3), t-Bu(4)) containing strongly electrondonating N-N′-N ligands, have been prepared by a metathesis reaction of [RhCl(2,6-(CH=R²)₂C₅H₃N)] (R² = i-Pr (1), t-Bu (2)) with NaOPh. These rhodium(I) phenoxide complexes 3 and 4, which are very sensitive to O₂ but stable towards H₂O, give with phenol the adducts [Rh(OPh) (2,6-(CH=NR²)₂C₅H₃N)] · HOPh (R2 = i-Pr (5), t-Bu (6)), which contain strong O-HO hydrogen bonds. The hydrogen bonded phenol could not be extracted with diethyl ether, while no exchange of the hydrogen bonded phenol and the phenoxide ligand in 4 is observed on the NMR time scale. However, a small excess of phenol results in exchange of the hydrogen bonded phenol, the coordinated phenoxide ligand and free phenol on the NMR time scale. Reaction of 3 and 4 with p-nitrophenol afforded [Rh(OC₆H₄-(NO₂-4))(2,6-(CH=R²)₂C₅H₃N)] · HOPh (R² = i-Pr (7), t-Bu (8)) in which the formed phenol is hydrogen bonded to the Rh(I)-OC₆H₄-(NO₂-4) moiety. The O-HO bond is less strong than in 5 and 6, as the hydrogen bonded phenol could be removed by diethyl ether.Treatment of 3 with acetyl chloride and benzoyl chloride in benzene at room temperature gave phenylacetate and RhCl₂(C(O)C₆H₃) (2,6(C(H)=N-i-Pr)₂C₅H₃N)] (15), and phenylbenzoate and [RhCl₂(C(O)Ph) (2,6-(C(H)=N-i-Pr)₂C₅H₃N)] (19), respectively. Complex 15 and the analogous complex [RhCl₂(C(O)CH₃) (2,6-(C(H)=N-t-Bu)₂C₅H₃N)] (16) could also be prepared directly from acetyl chloride and 1 or 2, respectively. The single crystal X-ray determination of complex 16, monoclinic, space group P2₁/_c, a = 10.0477(5), b= 11.7268(6), c= 19.2336(9) Å, β = 92.041(4)°, Z = 4, R₁ = 0.0281, shows that the acetyl group occupies an axial position, while the N-N′-N ligand is positioned equatorially. In solution this geometry remains unchanged as was shown by variable temperature ¹H NMR measurements. When the oxidative addition of acetyl chloride to 3 was carried out at −78°C in toluene the intermediate complex [RhCl(OPh) (C(O)Me) (2,6-(C(H)=N-i-Pr)₂C₅H₃N)] (11) could be isolated, which at room temperature reductively eliminates phenylacetate with formation of 1. Oxidative addition of acetyl chlori de to 4 at room temperature gives [RhCl(OPh) (C(O)Me) (2,6-(C(H)=Nt-Bu)₂C₅H₃N)] (12) which yields phenylacetate and 2 at 70°C in benzene by inductive elimination. Treatment of 3 with two equivalents of benzyl chloride afforded a mixture of [RhCl(OPh) (CH₂Ph) (2,6-(C(H)=N-i-Pr)₂C₅H₃N)] (13) and [RhCl₂(CH₂Ph) (2,6-(C(H)=N-i-Pr)₂C₅H₃N)] (17) and some non-characterizable organic products, while 4 only yielded [RhCl(OPh) (CH₂Ph) (2,6-(C(H)=N-tBu)₂C₅H₃N)] (14).