Synthesis of a Glucuronic Acid-Containing Thioglycoside Trisaccharide Building Block and Its Use in the Assembly of Cryptococcus Neoformans Capsular Polysaccharide Fragments

As part of an ongoing project aimed at identifying protective capsular polysaccharide epitopes for the development of vaccine candidates against the fungal pathogen Cryptococcus neoformans, the synthesis and glycosylation properties of a naphthalenylmethyl (NAP) orthogonally protected trisaccharide thioglycoside, a common building block for construction of serotype B and C capsular polysaccharide structures, were investigated. Et (benzyl 2,3,4-tri-O-benzyl-β-D-glucopyranosyl- uronate)-(1→2)-[2,3,4-tri-O-benzyl-β-D-xylopyranosyl-(1→4)]-6-O-benzyl-3-O-(2-naphthalenylmethyl)-1-thio-α-D-mannopyranoside was prepd. and used both as a donor and an acceptor in glycosylation reactions to obtain spacer equipped hexa- and heptasaccharide structures suitable either for continued elongation or for deprotection and printing onto a glycan array or conjugation to a carrier protein. The glycosylation reactions proceeded with high yields and α-selectivity, proving the viability of the building block approach also for construction of 4-O-xylosyl-contg. C. neoformans CPS structures

Identification and characterization of a glycosulfatase-encoding gene cluster in Bifidobacterium breve UCC2003

Bifidobacteria constitute a specific group of commensal bacteria, typically found in the gastrointestinal tract (GIT) of humans and other mammals. Bifidobacterium breve strains are numerically prevalent among the gut microbiota of many healthy breast-fed infants. In the current study, we investigated glycosulfatase activity in a bacterial nursling stool isolate, B. breve UCC2003. Two putative sulfatases were identified on the genome of B. breve UCC2003. The sulfated monosaccharide N-acetylglucosamine-6-sulfate (GlcNAc-6-S) was shown to support growth of B. breve UCC2003, while, N-acetylglucosamine-3-sulfate, N-acetylgalactosamine-3-sulfate and N-acetylgalactosamine-6-sulfate, did not support appreciable growth. Using a combination of transcriptomic and functional genomic approaches, a gene cluster, designated ats2, was shown to be specifically required for GlcNAc-6-S metabolism. Transcription of the ats2 cluster is regulated by a ROK-family transcriptional repressor. This study represents the first description of glycosulfatase activity within the Bifidobacterium genus. Bifidobacteria are saccharolytic organisms naturally found in the digestive tract of mammals and insects. Bifidobacterium breve strains utilize a variety of plant and host-derived carbohydrates which allow them to be present as prominent members of the infant gut microbiota as well as being present in the gastrointestinal tract of adults. In this study, we introduce a previously unexplored area of carbohydrate metabolism in bifidobacteria, namely the metabolism of sulfated carbohydrates. B. breve UCC2003 was shown to metabolize N-acetylglucosamine-6-sulfate (GlcNAc-6-S) through one of two sulfatase-encoding gene clusters identified on its genome. GlcNAc-6-S can be found in terminal or branched positions of mucin oligosaccharides, the glycoprotein component of the mucous layer that covers the digestive tract. The results of this study provide further evidence of this species' ability to utilize mucin-derived sugars, a trait which may provide a competitive advantage in both the infant and adult gut

A detailed picture of a protein–carbohydrate hydrogen-bonding network revealed by NMR and MD simulations

Cyanovirin-N (CV-N) is a cyanobacterial lectin with antiviral activity towards HIV and several other viruses. Here, we identify mannoside hydroxyl protons that are hydrogen bonded to the protein backbone of the CV-N domain B binding site, using NMR spectroscopy. For the two carbohydrate ligands Manα(1→2)ManαOMe and Manα(1→2) Manα(1→6)ManαOMe five hydroxyl protons are involved in hydrogen-bonding networks. Comparison with previous crystallographic results revealed that four of these hydroxyl protons donate hydrogen bonds to protein backbone carbonyl oxygens in solution and in the crystal. Hydrogen bonds were not detected between the side chains of Glu41 and Arg76 with sugar hydroxyls, as previously proposed for CV-N binding of mannosides. Molecular dynamics simulations of the CV-N/Manα(1→2)Manα(1→6)ManαOMe complex confirmed the NMR-determined hydrogen-bonding network. Detailed characterization of CV-N/mannoside complexes provides a better understanding of lectin-carbohydrate interactions and opens up to the use of CV-N and similar lectins as antiviral agents

Cryptococcus neoformans capsular GXM conformation and epitope presentation: a molecular modelling study

The pathogenic encapsulated Cryptococcus neoformans fungus causes serious disease in immunosuppressed hosts. The capsule, a key virulence factor, consists primarily of the glucuronoxylomannan polysaccharide (GXM) that varies in composition according to serotype. While GXM is a potential vaccine target, vaccine development has been confounded by the existence of epitopes that elicit non-protective antibodies. Although there is evidence for protective antibodies binding conformational epitopes, the secondary structure of GXM remains an unsolved problem. Here an array of molecular dynamics simulations reveal that the GXM mannan backbone is consistently extended and relatively inflexible in both C. neoformans serotypes A and D. Backbone substitution does not alter the secondary structure, but rather adds structural motifs: bDGlcA and bDXyl side chains decorate the mannan backbone in two hydrophillic fringes, with mannose-6-O-acetylation forming a hydrophobic ridge between them. This work provides mechanistic rationales for clinical observations—the importance of O-acetylation for antibody binding; the lack of binding of protective antibodies to short GXM fragments; the existence of epitopes that elicit non-protective antibodies; and the self-aggregation of GXM chains—indicating that molecular modelling can play a role in the rational design of conjugate vaccines

Interaction of five -mannose-specific lectins with a series of synthetic branched trisaccharides

The interaction of a series of synthetic, branched trisaccharides with five -mannose-specific lectins was studied by precipitation-inhibition assay. The branched methyl [alpha]--mannotrioside, [alpha]--Manp-(1-->3)-[[alpha]--Manp-(1-->6)-[alpha]--ManpOMe, the best inhibitor of the Con A--Dextran interaction, was 42 times more potent than [alpha]--ManpOMe, and 3-6 times more potent than the two trisaccharides substituted with -glucosyl groups, and 8-15 times those with -galactosyl groups. Surprisingly, methyl O-[alpha]--mannopyranosyl-(1-->3)-[alpha]--mannopyranoside was bound to Con A 8-fold more avidly than methyl [alpha]--mannopyranoside. However, the related pea lectin (PSA) was singularly different from Con A in its carbohydrate-binding activity, showing no significantly enhanced binding to any of the sugars examined. The trisaccharides containing terminal, nonreducing, (1-->3)-linked [alpha]--mannopyranosyl groups, i.e., [alpha]--Manp-(1-->3)-[[alpha]--Glcp-(1-->6)-[alpha]--ManpOMe, [alpha]--Manp-(1-->3)-][alpha]--Galp-(1-->6)]-[alpha]--ManpOMe, and [alpha]--Manp-(1-->3)-[[alpha]--Manp-(1-->6)]-[alpha]-- ManpOMe, were the best inhibitors of the snowdrop lectin (GNA)--mannan precipitation system. On the other hand, all branched trisaccharides exhibited very similar inhibitory potencies toward the daffodil lectin (NPA)--mannan interaction, whereas [alpha]--Manp-(1-->3)-[[alpha]--Galp-(1-->6)]-[alpha]--ManpOMe and [alpha]--Manp-(1-->3)-[[alpha]--Manp-(1-->6)]-[alpha]--ManpOMe were somewhat better inhibitors than the other branched trisaccharides of the amaryllis lectin (HHA)--mannan precipitation reaction. Of the oligosaccharides studied, the linear trisaccharide [alpha]--Manp-(1-->6)-[alpha]--Manp-(1-->6)--Man appears to be the most complementary to the combining site(s) of NPA and HHA.Peer Reviewedhttp://deepblue.lib.umich.edu/bitstream/2027.42/29275/1/0000334.pd

Метод проектів у процесі музично-виконавської підготовки майбутнього вчителя музики

(uk) У статті визначається сутність інтегрованого методу художньо-творчих проектів, розкривається його специфіка у процесі музично-виконавської підготовки майбутніх учителів музики.(ru) В статье определяется сущность интегрированного метода художественно-творческих проэктов, раскрывается его специфика в процессе музыкально-исполнительской подготовки будущих учителей музыки

The interaction of fluorinated glycomimetics with DC-SIGN: multiple binding modes disentangled by the combination of NMR methods and MD simulations

Fluorinated glycomimetics are frequently employed to study and eventually modulate protein–glycan interactions. However, complex glycans and their glycomimetics may display multiple binding epitopes that enormously complicate the access to a complete picture of the protein–ligand complexes. We herein present a new methodology based on the synergic combination of experimental 19F-based saturation transfer difference (STD) NMR data with computational protocols, applied to analyze the interaction between DC-SIGN, a key lectin involved in inflammation and infection events with the trifluorinated glycomimetic of the trimannoside core, ubiquitous in human glycoproteins. A novel 2D-STD-TOCSYreF NMR experiment was employed to obtain the experimental STD NMR intensities, while the Complete Relaxation Matrix Analysis (CORCEMA-ST) was used to predict that expected for an ensemble of geometries extracted from extensive MD simulations. Then, an in-house built computer program was devised to find the ensemble of structures that provide the best fit between the theoretical and the observed STD data. Remarkably, the experimental STD profiles obtained for the ligand/DC-SIGN complex could not be satisfactorily explained by a single binding mode, but rather with a combination of different modes coexisting in solution. Therefore, the method provides a precise view of those ligand–receptor complexes present in solution.We thank Agencia Estatal de Investigación (Spain) for grants RTI2018-094751-B-C21 and B-C22, CTQ2015-68756-R, and for FPI and FPU fellowships to J.D.M. and P.V., respectively, and for the Severo Ochoa Excellence Accreditation (SEV-2016-0644). J.J.-B. also thanks to the European Research Council (RECGLYCANMR, Advanced Grant no. 788143). S.O. thanks the SFI Award 13/IA/1959Peer reviewe

Fluorinated Carbohydrates as Lectin Ligands: Simultaneous Screening of a Monosaccharide Library and Chemical Mapping by F-19 NMR Spectroscopy

Molecular recognition of carbohydrates is a key step in essential biological processes. Carbohydrate receptors can distinguish monosaccharides even if they only differ in a single aspect of the orientation of the hydroxyl groups or harbor subtle chemical modifications. Hydroxyl-by-fluorine substitution has proven its merits for chemically mapping the importance of hydroxyl groups in carbohydrate-receptor interactions. F-19 NMR spectroscopy could thus be adapted to allow contact mapping together with screening in compound mixtures. Using a library of fluorinated glucose (Glc), mannose (Man), and galactose (Gal) derived by systematically exchanging every hydroxyl group by a fluorine atom, we developed a strategy combining chemical mapping and F-19 NMR T-2 filtering-based screening. By testing this strategy on the proof-of-principle level with a library of 13 fluorinated monosaccharides to a set of three carbohydrate receptors of diverse origin, i.e. the human macrophage galactose-type lectin, a plant lectin, Pisum sativum agglutinin, and the bacterial Gal-/Glc-binding protein from Escherichia coli, it became possible to simultaneously define their monosaccharide selectivity and identify the essential hydroxyls for interactionAgencia Estatal de Investigacion (Spain) Grants CTQ2015-64597-C2-1-P and 2-P, RTI2018-094751-B-C21 and C22, Severo Ochoa Excellence Accreditation (SEV-2016-0644) European Research Council (RECGLYCANMR, Advanced Grant No. 788143), and CIBERES, an initiative from the Spanish Institute of Health Carlos III. Science Foundation Ireland, SFI Award 13/IA/195

What is the sugar code?

54 p.-11 fig.A code is defined by the nature of the symbols, which are used to generate information-storing combinations (e.g. oligo- and polymers). Like nucleic acids and proteins, oligo- and polysac-charides are ubiquitous, and they are a biochemical platform for establishing molecular mes-sages. Of note, the letters of the sugar code system (third alphabet of life) excel in coding ca-pacity by making an unsurpassed versatility for isomer (code word) formation possible by var-iability in anomery and linkage position of the glycosidic bond, ring size and branching. The enzymatic machinery for glycan biosynthesis (writers) realizes this enormous potential for building a large vocabulary. It includes possibilities for dynamic editing/erasing as known from nucleic acids and proteins. Matching the glycome diversity, a large panel of sugar receptors (lectins) has developed based on more than a dozen folds. Lectins ‘read’ the glycan-encoded information. Hydrogen/coordination bonding and ionic pairing together with stacking and C-H/- interactions as well as modes of spatial glycan presentation underlie the selectivity and specificity of glycan-lectin recognition. Modular design of lectins together with glycan display and the nature of the cognate glycoconjugate account for the large number of post-binding events. They give an entry to the glycan vocabulary its functional, often context-dependent meaning(s), hereby building the dictionary of the sugar codeFunding by the NIH grant CA242351 (to M.C.), the SFI Investigator Programme Awards 16/IA/4419 (to P.V.M.) and 13/IA/1959 & 16/RC/3889 (to S.O.) as well as by the grant BFU 2016-77835-R of the Spanish Ministry of Economy, Industry and Competitiveness (to A.R.).Peer reviewe