Teruaki Hasegawa

C6-Modifications on chitosan to develop chitosan-based glycopolymers and their lectin-affinities with sigmoidal binding profiles

Chitosan-based glycopolymers having multiple β-lactosides exclusively at their C6-positions were successfully synthesized from partially deacetylated chitin through perfect N-deacetylation/phthaloylation and C6-selective bromination/azidation to afford 6-azide-6-deoxy-N-phthaloyl-chitosan and the subsequent Cu(+)-catalyzed Huisgen cycloadditions using alkyne-terminated β-lactoside and/or quaternary ammonium modules followed by dephthaloylations. Lectin-affinities of the resultant chitosan-based glycopolymers were assessed through fluorescence titration assays to show their unique sigmoidal binding profiles with amplified binding constants.

Inulin-based glycopolymer: Its preparation, lectin-affinity and gellation property

The glycopolymer composed of an inulin scaffold and pendent β-lactosides was developed from commercially available inulin through sequential chemical modification processes composed of tosylation, azidation, and the subsequent Huisgen cyclocoupling with an alkyne-terminated β-lactoside. The resultant inulin-based glycopolymer has unique dual affinity towards β-galactoside and α-glucoside specific lectins which is attributable to its pendent β-lactosides and terminal α-glucoside. Its gellation property was also accessed to find that the inulin-based glycopolymer forms hydrogels whose critical gellation concentration (CGC) was lower than that required for hydrogels made from native inulin. Drug release properties of the inulin-based glycopolymer were also discussed in this paper.

Curdlan as a Polymeric Starting Material to Access C6-Modified Glucose Derivatives

We evaluated the potential of a linear β-1,3-glucan (curdlan) as a starting material to access C6-modified glucose derivatives and found that 6-bromo-6-deoxyglucose, 6-azide-6-deoxyglucose, and 6-acetamido-6-deoxyglucose could be readily prepared from curdlan through its C6-selective and quantitative modifications and subsequent acid-catalyzed hydrolysis.

Tosylated and azidated inulins as key substrates for further chemical modifications to access inulin-based advanced materials: An inulin-based glycocluster

We successfully synthesized inulin tosylates by treating commercially available inulin with tosyl chloride and triethylamine in N,N-dimethylacetoamide at the ambient temperature for 24h. The subsequent S(N)2 reactions using sodium azide afford inulin azides that can act as useful substrates for the following Huisgen cycloaddition with alkyne-terminated β-lactoside. The resultant inulin derivative having multiple β-lactosides has excellent affinity towards a β-lactoside binding lectin (RCA(120)). This synthetic strategy has various advantages, such as non-fragmentation of the inulin mainchain and wide applications for various alkyne-terminated functional units. Our strategy can be, therefore, used to develop various inulin derivatives that are applicable for food and medicinal industries.

Preparation and functional analysis of gossypols having two carbohydrate appendages with enaminooxy linkages

We developed new gossypol (Gos)-based glycoconjugates through dehydration condensation of native Gos and chemically modified glycosides having aminooxy groups. The resultant glycoconjugates (glycoGos) were resistant to hydrolysis, although they were light-sensitive and slowly decomposed even under indoor lighting. The glycoGos also exhibited improved water solubility compared with native Gos, but their saturated concentrations in water were still low (6.4-17 μM), due to their hydrophobic naphthyl rings. We also carried out WST-8 assays to assess the anticancer activity of the glycoGos on DLD-1 and HepG2 cells and found that the glycoGos having β-lactosides and having β-galactosides (specific ligands for asialoglycoprotein receptors) showed enhanced anticancer activity on HepG2 cells.