Distribution of iduronate 2-sulphate residues in heparan sulphate. Evidence for an ordered polymeric structure.
Affiliation
Department of Clinical Research, University of Manchester, Christie Hospital and Holt Radium Institute, U.K.Issue Date
1991-02-01
Metadata
Show full item recordAbstract
The structure of human skin fibroblast heparan sulphate has been examined by depolymerization with heparinase, which specifically cleaves highly sulphated disaccharides of structure GlcNSO3 (+/-6S)-alpha 1,4IdoA(2S) [N-sulphated glucosamine (6-sulphate)-alpha 1,4-iduronic acid 2-sulphate]. Heparan sulphate contained only a small proportion (approximately 10%) of linkages susceptible to this enzyme. The major products of depolymerization with heparinase were large oligosaccharides with an average molecular mass of 10 kDa (dp approximately 40, where dp is degree of polymerization; for disaccharides, dp = 2 etc.) as assessed by gel filtration on Sepharose CL-6B, compared with a molecular mass of 45 kDa (dp approximately 200) for the intact chains. The large heparinase-resistant oligosaccharides were highly susceptible to depolymerization with the enzyme heparitinase, which cleaves heparan sulphate in areas of low sulphation, where N-acetylated disaccharides [GlcNAc-alpha 1,4GlcA (N-acetylglucosaminyl-alpha 1,4-glucuronic acid)] are the predominant structural unit. Further analysis of the location of the heparinase cleavage sites indicated that they were predominantly found in a central position in GlcNSO3-alpha 1,4IdoA repeat sequences of average length four to seven disaccharides (dp 8-14). These results indicate that heparinase cleaves heparan sulphate in approximately four or five N-sulphated domains, each domain containing a cluster of two or three susceptible disaccharides; the domains are separated by long N-acetyl-rich sequences that are markedly deficient in sulphate groups. On the basis of these findings a model is proposed which depicts heparan sulphate as an ordered polymeric structure composed of an alternate arrangement of sulphate-rich and sulphate-poor regions. The sulphate-rich regions are likely to be flexible areas of the chain because of their high content of the conformationally versatile IdoA and IdoA(2S) residues. The model has important implications for the biosynthesis and functions of heparan sulphate.Citation
Distribution of iduronate 2-sulphate residues in heparan sulphate. Evidence for an ordered polymeric structure. 1991, 273 ( Pt 3):553-9 Biochem. J.Journal
Biochemical JournalPubMed ID
1996955Type
ArticleLanguage
enISSN
0264-6021Collections
Related articles
- Sequence analysis of heparan sulphate indicates defined location of N-sulphated glucosamine and iduronate 2-sulphate residues proximal to the protein-linkage region.
- Authors: Turnbull JE, Gallagher JT
- Issue date: 1991 Jul 15
- Molecular organization of heparan sulphate from human skin fibroblasts.
- Authors: Turnbull JE, Gallagher JT
- Issue date: 1990 Feb 1
- Heterogeneity of cell-associated and secretory heparan sulphate proteoglycans produced by cultured human neuroblastoma cells.
- Authors: Hampson IN, Kumar S, Gallagher JT
- Issue date: 1984 Sep 28
- Analysis of heparan-sulphate chains and oligosaccharides from proliferating and quiescent fibroblasts. A proposed model for endoheparanase activity.
- Authors: Schmidtchen A, Fransson LA
- Issue date: 1994 Jul 1
- Analysis of glycosaminoglycan chains from different proteoglycan populations in human embryonic skin fibroblasts.
- Authors: Schmidtchen A, Fransson LA
- Issue date: 1992 Sep 1