Synthesis of an asparagine-linked heptasaccharide - Basic structure of N-glycans

Gal beta>(*) over bar * (1-4)GlcNAc beta>(*) over bar * (1-2)Man alpha>(*) over bar * (1-3)[Man alpha>(*) over bar * (1-6)]Man beta>(*) over bar * (1- 4)-GlcNAc beta>(*) over bar * (1-N)Asn (1) was disconnected into building b locks 2-6. N-Dimethylmaleoyl (DMM) protected glucosamine 3 was readily obta ined from glucosamine. Transformation of 3 into 4-O-unprotected glucosamine derivatives 9, 14, and 18 furnished the intermediates required for the inc orporation of the three differently linked glucosamine residues. Thus, disa ccharide 20 was obtained from acceptor 9 and glucosyl donor 19 and converte d into protected Man beta>(*) over bar * (1-4)GlcNAc disaccharide donor 5 b y inversion of the configuration at C-2 of the glucose residue. Glycosylati on of acceptor 18 with known galactosyl donor 26 afforded protected lactosa mine donor 6. The synthesis of asparagine building block 2 and of mannosyl donor 4 has already been reported. With building blocks 2-6 in hand, the sy nthesis of 1 was accomplished. Glycosylation of acceptor 14 with donor 5 ga ve trisaccharide 29 which was transformed into acceptor 30. Treatment of 30 with glycosyl donor 4 provided tetrasaccharide intermediate 31. Its transf ormation into 2d-O-unprotected acceptor 33 and then reaction with disacchar ide donor 6 furnished hexasaccharide 34. Removal of the 4c,6c-O-benzylidene group gave 4c,6c-O-unprotected acceptor 35 which, on glycosylation with do nor 4, led to heptasaccharide 36. Replacement of the N-DMM groups by N-acet yl groups and removal of all O-acyl groups, followed by transformation of t he C-la azido group into an amino group, and attachment of asparagine build ing block 2 led to the desired heptasaccharide beta -linked to asparagine 3 9. Hydrogenolysis of all O-benzyl groups afforded target molecule 1.