Ian Cumpstey

Iridium-catalysed condensation of alcohols and amines as a method for aminosugar synthesis

Primary carbohydrate amines at primary and secondary carbons are alkylated by alcohols in the presence of [Cp*IrCl(2)](2). When primary carbohydrate alcohols are used as the coupling partners and in the presence of Cs(2)CO(3), amine-linked pseudodisaccharides are obtained. Secondary carbohydrate alcohols are unaffected under these conditions, which allows regioselective reactions.

Intramolecular aglycon delivery

A Minireview with 51 references covering the two-step tethering and intramolecular glycosylation process termed intramolecular aglycon delivery (IAD). Specifically, glycosylation reactions where the tethered oxygen acts as nucleophile are covered. In the majority of cases, tethering to O-2 of a glycosyl donor ensures formation of a 1,2-cis glycoside after intramolecular glycosylation.

Stereospecific debenzylative cycloetherification of carbohydrate-derived allylic alcohols, ethers and esters to form vinyl C-furanosides

Benzyl ether protected polyhydroxylated alkene compounds containing allylic alcohol, ether or ester functionality undergo a stereospecific cyclisation reaction upon treatment with TFA-acetonitrile-toluene with inversion of configuration at the allylic position and loss of a benzyl ether to give tetrahydrofurans.

Studies on the synthesis of valienamine and 1-epi-valienamine starting from d-glucose or l-sorbose

Two synthetic routes to a carbocyclic precursor to valienamine are reported, starting from either D-glucose or L-sorbose and using ring-closing metathesis as a key step. A low-yielding synthesis of 1-epi-valienamine is reported. Results from an abortive third possible route to valienamine based on an early introduction of nitrogen are discussed.

Unusual synthesis of carbohydrate sec-sec ether-linked pseudodisaccharides

In this paper, we describe the synthesis of sec-sec ether-linked pseudodisaccharides by the coupling of various secondary carbohydrate alcohols with di-O-isopropylidene allose 3-O-triflate. Reactions proceeded with inversion of configuration to give the 3-substituted di-O-isopropylidene glucose derivatives. The crystal structure of a sec-sec ether-linked pseudodisaccharide is reported.

Synthesis of carbasugar-containing non-glycosidically linked pseudodisaccharides and higher pseudooligosaccharides

This minireview covers synthetic methods towards carbasugar-containing non-glycosidically linked pseudodisaccharides or higher pseudooligosaccharides. Carbocyclic pyranose mimetics (saturated or unsaturated between C-5 and C-5a) are linked by ether, thioether or amine bridges to carbohydrates or other carbasugars.

Synthesis and conformational analysis of carbasugar bioisosteres of α-l-iduronic acid and its methyl glycoside

The synthesis of two novel carbasugar analogues of alpha-L-iduronic acid is described in which the ring-oxygen is replaced by a methylene group. In analogy with the conformational equilibrium described for alpha-L-IdopA, the conformation of the carbasugars was investigated by (1)H and (13)C NMR spectroscopy. Hadamard transform NMR experiments were utilised for rapid acquisition of (1)H,(13)C-HSQC spectra and efficient measurements of heteronuclear long-range coupling constants. Analysis of (1)H NMR chemical shifts and J(H,H) coupling constants extracted by a total-lineshape fitting procedure in conjunction with J(H,C) coupling constants obtained by three different 2D NMR experiments, viz., (1)H,(13)C-HSQC-HECADE, J-HMBC and IPAP-HSQC-TOCSY-HT, as well as effective proton-proton distances from 1D (1)H,(1)H T-ROE and NOE experiments showed that the conformational equilibrium [formula in text] is shifted towards (4)C(1) as the predominant or exclusive conformation. These carbasugar bioisosteres of alpha-l-iduronic acid do not as monomers show the inherent flexibility that is anticipated to be necessary for biological activity.

Carbasugar-thioether pseudodisaccharides related to N-glycan biosynthesis

Analogues of the alpha-Glcp-(1-->3)-alpha-Glcp and alpha-Glcp-(1-->3)-alpha-Manp disaccharides (representing the two alpha-gluco linkages cleaved by alpha-Glucosidase II in N-glycan biosynthesis) in which the non-reducing-end sugar is replaced by a carbasugar and the inter-glycosidic oxygen by a sulfur were synthesised. The key coupling step was an S(N)2 displacement of an equatorial triflate at C-1 of the carbasugar by C-3 gluco or manno thiolates with inversion of configuration to give thioether pseudodisaccharides with axial substitution at C-1 of the carbasugar. The deprotected pseudodisaccharides failed to inhibit the action of alpha-Glucosidase II as measured both by an in vitro assay and by free oligosaccharide (FOS) analysis from cell studies.

Synthesis and α-Glucosidase II inhibitory activity of valienamine pseudodisaccharides relevant to N-glycan biosynthesis

Valienol-derived allylic C-1 bromides have been used as carbaglycosyl donors for α-xylo configured valienamine pseudodisaccharide synthesis. We synthesised valienamine analogues of the Glc(α1→3)Glc and Glc(α1→3)Man disaccharides representing the linkages cleaved by α-Glucosidase II in N-glycan biosynthesis. These (N1→3)-linked pseudodisaccharides were found to have some α-Glucosidase II inhibitory activity, while two other (N1→6)-linked valienamine pseudodisaccharides failed to inhibit the enzyme.

Carbasugar analogues of galactofuranosides: β-O-linked derivatives and towards β-S-linked derivatives.

A selectively protected carbasugar analogue of β-galactofuranose was synthesised from glucose using ring-closing metathesis as the key step. The carbasugar was converted into an α-galacto configured 1,2-epoxide, which was an effective electrophile in Lewis acid catalysed coupling reactions with alcohols. The epoxide was opened with regioselective attack at C-1 to give β-galacto configured C-1 ethers. Using carbohydrates as nucleophiles, we synthesised a number of pseudodisaccharides. The epoxide was also regioselectively opened at C-1 with a sulfur nucleophile under basic conditions to give a β-galacto configured C-1 thioether.