Distinguishing glucuronic from iduronic acid in glycosaminoglycan tetrasaccharides by using electron detachment dissociation.
(33/87)
Distinguishing the epimers iduronic acid (IdoA) and glucuronic acid (GlcA) has been a long-standing challenge for the mass spectrometry analysis of glycosaminoglycan (GAG) oligosaccharides. In this work, electron detachment dissociation (EDD) and Fourier transform ion cyclotron resonance mass spectrometry is shown to provide mass spectral features that can distinguish GlcA from IdoA in heparan sulfate (HS) tetrasaccharides. EDD of HS tetrasaccharide dianions produces a radical species that fragments to produce information-rich glycosidic and cross-ring product ions which can be used to determine the sites of acetylation/sulfation. More significantly, EDD of HS tetrasaccharide epimers produces diagnostic product ions that can be used to distinguish IdoA from GlcA. These diagnostic product ions are not observed in the tandem mass spectra obtained by collisionally activated dissociation or infrared multiphoton dissociation of the tetrasaccharides, suggesting a radical-initiated mechanism for their formation. Differences in the observed product ions obtained by EDD of the tetrasaccharide epimers can be rationalized by simple alpha-cleavage of an oxy radical located at C2 or C3 or a radical at C3 or C4. These radicals are proposed to arise from a hydrogen rearrangement in which a hydrogen atom is transferred from the C2 or C3 hydroxyl group or C3 or C4 to a carboxy radical at C5. This hydrogen transfer depends on the proximity of the carboxy radical to the hydroxyl group on C2 or C3 or the hydrogen on C3 or C4 and is thus influenced by C5 stereochemistry. These epimer-sensitive fragmentations should allow this approach to be applied to the structural analysis of a wide variety of GAG oligosaccharides. (+info)
Characterization of anti-heparan sulfate phage display antibodies AO4B08 and HS4E4.
(34/87)
Heparan sulfates (HS) are linear carbohydrate chains, covalently attached to proteins, that occur on essentially all cell surfaces and in extracellular matrices. HS chains show extensive structural heterogeneity and are functionally important during embryogenesis and in homeostasis due to their interactions with various proteins. Phage display antibodies have been developed to probe HS structures, assess the availability of protein-binding sites, and monitor structural changes during development and disease. Here we have characterized two such antibodies, AO4B08 and HS4E4, previously noted for partly differential tissue staining. AO4B08 recognized both HS and heparin, and was found to interact with an ubiquitouys, N-, 2-O-, and 6-O-sulfated saccharide motif, including an internal 2-O-sulfate group. HS4E4 turned out to preferentially recognize low-sulfated HS motifs containing iduronic acid, and N-sulfated as well as N-acetylated glucosamine residues. Contrary to AO4B08, HS4E4 did not bind highly O-sulfated structures such as found in heparin. (+info)
Interactions of hepatocyte growth factor/scatter factor with various glycosaminoglycans reveal an important interplay between the presence of iduronate and sulfate density.
(35/87)
Hepatocyte growth factor/scatter factor (HGF/SF) has a cofactor requirement for heparan sulfate (HS) and dermatan sulfate (DS) in the optimal activation of its signaling receptor MET. However, these two glycosaminoglycans (GAGs) have different sugar backbones and sulfation patterns, with only the presence of iduronate in common. The structural basis for GAG recognition and activation is thus very unclear. We have clarified this by testing a wide array of natural and modified GAGs for both protein binding and activation. Comparisons between Ascidia nigra (2,6-O-sulfated) and mammalian (mainly 4-O-sulfated) DS species, as well as between a panel of specifically desulfated heparins, revealed that no specific sulfate isomer, in either GAG, is vital for interaction and activity. Moreover, different GAGs of similar sulfate density had comparable properties, although affinity and potency notably increase with increasing sulfate density. The weaker interaction with CS-E, compared with DS, shows that GlcA-containing polymers can bind, if highly sulfated, but emphasizes the importance of the flexible IdoA ring. Our data indicate that the preferred binding sites in DS in vivo will be comprised of disulfated, IdoA(2S)-containing motifs. In HS, clustering of N-/2-O-/6-O-sulfation in S-domains will lead to strong reactivity, although binding can also be mediated by the transition zones where sulfates are mainly at the N- and 6-O- positions. GAG recognition of HGF/SF thus appears to be primarily driven by electrostatic interactions and exhibits an interesting interplay between requirements for iduronate and sulfate density that may reflect in part a preference for particular sugar chain conformations. (+info)
Sequence analysis of heparan sulphate indicates defined location of N-sulphated glucosamine and iduronate 2-sulphate residues proximal to the protein-linkage region.
(36/87)
A strategy that we originally used to identify an N-acetylated domain adjacent to the protein-linkage sequence of heparan sulphate proteoglycan (HSPG) [Lyon, Steward, Hampson & Gallagher (1987) Biochem. J. 242, 493-498] has been adapted for analysis of the location of GlcNSO3-HexA and GlcNSO3(+/- 6S)-IdoA(2S) units most proximal to the core protein. [3H]Glucosamine-labelled HSPG from human skin fibroblasts was depolymerized by using HNO2 or heparinase under conditions that allowed cleavage of all susceptible linkages. The degraded PG was coupled to Sepharose beads through the protein component, enabling specific recovery of protein-linked resistant oligosaccharides. These were released by treatment with alkaline borohydride and analysed by gel filtration and gradient PAGE. This strategy allowed investigation of the sequence of sugar residues along the chain relative to a common reference point (i.e. the reducing end of the chain). HNO2 scission confirmed the presence of a well-defined N-acetylated sequence predominantly 9-12 disaccharide units in length proximal to the core protein. Heparinase scission produced two classes of oligosaccharides (Mr approx. 7000 and 15,000) with the general formula: IdoA(2S)-GlcNSO3-[HexA-GlcNR]n-HexA-GlcNSO3-[Hex A-GlcNAc]9 12-GlcA-Gal-Gal-Xyl in which the average value for n is 1-2 for the 7000-Mr species and approx. 22 for the 15,000-Mr species. The latter oligosaccharides extend to about one-third of the total length of the HS chains (Mr approx. 45,000). HNO2 scission of these oligosaccharides enabled hypothetical models for their sequence to be proposed. The general arrangement of N-sulphated and N-acetylated disaccharides between the proximal GlcNSO3 and terminal IdoA(2S) residues of the 15,000-Mr fragment was similar to that in the original polysaccharide, suggesting the possibility of a tandemly repeating pattern in the sequence of HS. (+info)
Electron-induced dissociation of glycosaminoglycan tetrasaccharides.
(37/87)