Maria Carmelita Z. Kasuya

Azido glycoside primer: a versatile building block for the biocombinatorial synthesis of glycosphingolipid analogues

A lactoside primer, 12-azidododecyl beta-lactoside, was synthesized via the Koenigs-Knorr method by glycosylation of 1,12-dodecyldiol with perbenzoylated lactosyl bromide. The presence of the 2-O-acyl substituent in the donor gave the beta-lactoside, and an excess of acceptor ensured monoglycosylation of the diol. Mesylation of the omega-hydroxyl group in the aglycon, followed by displacement of the mesylate with azide and subsequent O-debenzoylation gave the desired omega-azidododecyl beta-lactoside. The azido glycoside primer was examined in mouse B16 melanoma cells for its feasibility as a building block for oligosaccharide biosynthesis. Uptake of the azido glycoside primer by B16 cells resulted in the sialylation of the galactose residue of the primer to give a glycosylated product having the same glycan as in ganglioside GM3. After 24 h incubation of B16 cells with the primers, the amount of sialylated omega-azidododecyl beta-lactoside primer was 75% of the amount of sialylated n-dodecyl beta-lactoside. However, after 48 h incubation, both primers gave equal amounts of the sialylated products. Interestingly, the remaining azido glycoside primer after 48 h incubation was 5.6-fold greater than that of the alkyl primer, indicating degradation of the alkyl primer to a larger extent than the omega-azido glycoside primer. The facile chemical synthesis and the efficient uptake in cells make the azido glycoside primer a versatile building block for the biocombinatorial synthesis of glycolipid oligosaccharides.

Effect of Anomeric Linkage on the Sialylation of Glycosides by Cells

The synthesis of sialylated glycosides using saccharide primers and cells was investigated. α · and β · Saccharide primers were chemically synthesized and introduced into B16 melanoma cells to prime oligosaccharide synthesis. Incorporation of α‐ and β‐dodecyl lactosides into B16 cells resulted in the sialylation of the galactose residue to give GM3‐type oligosaccharides. The β‐dodecyl galactoside primer was sialylated but the α‐dodecyl galactoside primer was not. Both the α‐ and β‐dodecyl glucoside primers were not elongated. In the glycosylation of primers by cells, this research confirmed that sialyl transferases tolerate acceptor modifications and are permissive to primer elongation regardless of the α‐ or β‐linkage to the aglycon unit. However, the presence of the terminal galactose residue that is β‐linked to the adjacent saccharide or aglycon unit is essential for sialylation by cellular enzymes to occur.

Alternative methods of globotrioside production using Vero cells: a microcarrier system procedure

BackgroundGlycolipids are one component of cell membranes, and are found most prevalently at the surface of the plasma membrane. Animal cells take in amphipathic glycosides, which are later glycosylated after assimilation in biosynthetic pathways. Gycosylated glycosides are released outside of cells to the surrounding culture medium. This represents an accessible method of obtaining complex glycosides.ResultsVero cells are sensitive to Shiga toxins and are known to express the glycosides globotriaosyl ceramide (Gb3) and globotetraosyl ceramide (Gb4) on the surface of the plasma membrane. By administering amphipathic lactosides to Vero cells, the above mentioned glycolipids could be produced by the action of cellular enzymes. In our study, the optimum conditions (seeded cell number, incubated time period, 12-azidododecyl lactoside concentration and medium volume) for the production of Gb3 analogue were investigated. The 87.9 μg/100 mm dish (11.7 % yield) Gb3 analogue was produced under appropriate conditions. The large-scale culture of Vero cells using a microcarrier culture method with repetitions produced about 30 mg of the Gb3 analogue.ConclusionThe mass production of glycosides in Vero cells was carried out on a microcarrier with repeated administration of 12-azidododecyl lactoside. The results indicated that the use of both a microcarrier culture and repetition were highly effective in the production of Gb3, Gb4 and sialyl lactoside (GM3) type-oligosaccharides.

Development of Membrane Filter with Oligosaccharide Immobilized by Click Chemistry for Influenza Virus Adsorption

Membranes with immobilized GM3-type oligosaccharide were prepared and influenza virus adsorption was evaluated. GM3-type oligosaccharide which has azido group in the aglycon was synthesized by saccharide primer method. The azido group was used for combination by click chemistry with alkyne which is introduced to membranes. The posi- tion of the azido group in the aglycon of GM3-type oligosaccharide was either the farthest (12-azidododecyl), or the near- est (2-azidododecyl). The azido group in the farthest position showed higher reactivity with alkyne on the membrane than the one in the nearest the GM3-type oligosaccharide. Moreover, the membrane immobilized GM3-type oligosaccharide showed adsorption ability of influenza virus.

The chemical synthesis of a cyclic oligosaccharide derivative with branching

Abstract A cyclic oligosaccharide derivative was synthesized by cationic ring-opening polymerization of an anhydrodisaccharide derivative under high vacuum in dichloromethane with 20 mol% of PF 5 as initiator. Analysis of the spectral results showed that the oligomer chain is composed of only 3 glucose units connected by α-1,6 linkages with a glucopyranosyl branching unit at C-4 of each sugar residue in the main chain.

Large scale biosynthesis of ganglioside analogues by RERF-LC-AI cells cultured in HYPERFlask.

The efficient production of ganglioside analogues was accomplished using RERF-LC-AI cells cultured in HYPERFlask (High Yield PERformance Flask). Eight kinds of ganglioside analogues (GM3, GM2, sialylparagloboside, GD3, di-sialylated lacto-N-tetraose, and another three kinds of analogues with intricate structures) were synthesized by the saccharide primer method using lung squamous-cell carcinoma line RERF-LC-AI and 12-azidododecyl β-lactoside primer. The yield for each analogue obtained using HYPERFlask was higher than yields obtained from 100-mm dishes.

Immobilization of fluorous oligosaccharide recognized by influenza virus on polytetrafluoroethylene filter

The lactoside with PEG-fluorous tag was introduced to BHK-21(C-13) cells to generate a GM3-type oligosaccharide (Siaα2-3Galβ1-4Glc). The GM3-type oligosaccharide obtained was easily immobilized by spotting onto commercially available polytetrafluoroethylene (PTFE) filter through non-covalent fluorous affinity and simply assessed by dot blot method using the interaction of carbohydrate- with proteins which recognize sialic acid such as virus membrane proteins.

Easy production of a glycolipid analogue using animal cells in culture.

A glycolipid analogue, GM4‐type ganglioside, was obtained by a combination of chemical synthesis and biosynthetic processes in animal cells with dodecyl β‐D‐galactoside (Gal C12) as primer. The primer was conveniently prepared in two steps: glycosylation, followed by deacetylation. The primer was introduced to mouse melanoma B16 cells to serve as substrate for cellular, enzyme‐catalyzed glycosylation. Incubation of the cells in the presence of the primer resulted in sialylation of the galactose residue to afford a GM4 analogue that was released from the cells to the culture medium. The strategy of preparation of the GM4 analogue described in this study is a viable alternative to the existing methods. The saccharide‐primer method is fast, convenient, not requiring expensive enzymes and glycosyl donors, and highly stereoselective.

Influence of passage number on glycosylation of alkyl lactosides by Madin-Darby canine kidney (MDCK) cells

The cell function on saccharide biosynthesis can be evaluated by employing the saccharide primer method. This study demonstrated that the characteristics of Madin-Darby canine kidney (MDCK) cells changed in relation with passage number when 12-azidododecyl β-lactoside (Lac-12N(3) primer) was incorporated into MDCK cells and afforded GM3-, GD3-, sialylparagloboside (SPG), and NeuAc-Gal-GlcNAc-Gal-GlcNAc-Lac-type oligosaccharides. By measuring the amount of glycosylated products from relatively early to late passage numbers, results showed that there was an appropriate passage number that optimized oligosaccharide production and that the higher passage number resulted to a decrease in oligosaccharide production. Moreover, results suggested that aside from sialyltransferase, the activity of several kinds of enzymes that control the amount of saccharide production was presumably affected depending upon the biological senescence.

Thiolactosides: Scaffolds for the Synthesis of Glycolipids in Animal Cells

Various glycolipids were synthesized using thiolactosides as scaffolds for glycosylation in animal cells. The basic building blocks, n-dodecyl β-D-thiolactoside (β-LacSC12) and n-dodecyl α-D-thiolactoside (α-LacSC12), were chemically synthesized in 2 steps: glycosylation followed by deacylation. The thiolactosides were administered to animal cells in culture and served as substrates for cellular enzyme-catalyzed glycosylation. Incubation of mouse melanoma B16 cells in the presence of β-LacSC12 or α-LacSC12 resulted in sialylation of the terminal galactose residue and gave a GM3-type ganglioside. Administration of β-Lac SC12 in Madin-Darby canine kidney (MDCK) cells likewise gave a GM3-type ganglioside. On the other hand, introduction of β-LacSC12 in African green monkey kidney (Vero) cells gave Gb3- and Gb4-type glycolipids aside from GM3-type ganglioside. In the course of the study, significant changes in B16 cell morphology and elevated secretion of melanin were also observed.