Structural diversity of N-sulfated heparan sulfate domains: distinct modes of glucuronyl C5 epimerization, iduronic acid 2-O-sulfation, and glucosamine 6-O-sulfation

F Safaiyan, U Lindahl, M Salmivirta - Biochemistry, 2000 - ACS Publications
F Safaiyan, U Lindahl, M Salmivirta
Biochemistry, 2000ACS Publications
The N-sulfated regions (NS domains) represent the modified sequences of heparan sulfate
chains and mediate interactions of the polysaccharide with proteins. We have investigated
the relationship between the type/extent of polymer modification and the length of NS
domains in heparan sulfate species from human aorta, bovine kidney, and cultured NMuMG
and MDCK cells. C5 epimerization of d-glucuronic acid to l-iduronic acid was found to be
extensive and essentially similar in all heparan sulfate species studied, regardless of …
The N-sulfated regions (NS domains) represent the modified sequences of heparan sulfate chains and mediate interactions of the polysaccharide with proteins. We have investigated the relationship between the type/extent of polymer modification and the length of NS domains in heparan sulfate species from human aorta, bovine kidney, and cultured NMuMG and MDCK cells. C5 epimerization of d-glucuronic acid to l-iduronic acid was found to be extensive and essentially similar in all heparan sulfate species studied, regardless of domain size, whereas the subsequent 2-O-sulfation of the formed iduronic acid residues varies appreciably. In aorta heparan sulfate, up to 90% of the formed iduronate residues were 2-O-sulfated, whereas in kidney heparan sulfate 2-O-sulfation occurred only in ≤50% of the iduronate residues. The degree of 2-O-sulfation was consistently increased with increasing NS domain length, suggesting a correlation between 2-O-sulfation efficiency and length of the polymeric substrate during heparan sulfate biosynthesis. By contrast, 6-O-sulfation of glucosamine units did not correlate to domain size. 6-O-Sulfation exceeded 2-O-sulfation in NS domains from kidney heparan sulfate, but was very low in aorta heparan sulfate. Remarkably, total O-sulfation of NS domains, i.e., the sum of 2-O- and 6-O-sulfate groups, was highly similar in all heparan sulfate samples investigated. The results reveal marked tissue-specific variation in the sulfation patterns of NS domains and indicate previously unrecognized distinctions in the coordination of the three polymer modification reactions during heparan sulfate biosynthesis.
ACS Publications