Structural studies of heparan sulfate hexasaccharides: new insights into iduronate conformational behavior.

There is a growing opinion that the conformational dynamics within HS chains is critical to their observed biological activities. Investigations into HS conformational dynamics are problematic, given the structural complexity and heterogeneity of HS chains. However, this goal will be more obtainable once we understand the important roles HS sequence/sulfation patterns play in determining the conformational dynamics of iduronate units. This is the first study to compare isomers of N-sulfated oligosaccharides, with respect to the conformational versatility of their internal iduronates. Characterization by NMR spectroscopy of two HS oligosaccharides derived from porcine mucosal HS enabled the measurement of iduronate coupling constants, while under the influence of different flanking saccharide sequences. By fitting our coupling constant data to a new set of theoretical coupling constants, calculated using explicit water molecular dynamic simulations, we are able to offer new insights into the role sequence/sulfation patterns play in influencing iduronate conformational behavior. Fitting of experimental data, using our new theoretically derived coupling constants, suggests that replacement of the N-sulfate group to the reducing side of IdoUA by an N-acetyl group has little effect on the balance of IdoUA conformational equilibrium. Fitting of coupling constants for sequences GlcNS-IdoUA(2S)-GlcNS and GlcNS(6S)-IdoUA(2S)-GlcNS suggests that the flanking 6-O-sulfate group alters the balance of the IdoUA(2S) equilibrium more toward the (2)S0 conformation. There is also the suggestion that a cooperative effect may exist for N- and 6-O sulfation. These observations could be the key to understanding the important regulatory function attributed to 6-O-sulfation within HS chains.

Evidence that heparin saccharides promote FGF2 mitogenesis through two distinct mechanisms.

Heparin-like saccharides play an essential role in binding to both fibroblast growth factors (FGF) and their receptors at the cell surface. In this study we prepared a series of heparin oligosaccharides according to their size and sulfation level. We then investigated their affinity for FGF2 and their ability to support FGF2 mitogenesis of heparan sulfate-deficient cells expressing FGFR1c. Tetra- and hexasaccharides bound FGF2, but failed to dimerize the growth factor. Nevertheless, these saccharides promoted FGF2-mediated cell growth. Furthermore, whereas enzymatic removal of the non-reducing end 2-O-sulfate group had little effect on the 1:1 interaction with FGF2, it eliminated the mitogenic activity of these saccharides. This evidence supports the symmetric two-end model of ternary complex formation. In contrast, even at very low concentrations, octasaccharide and larger heparin fragments conferred a potent mitogenic activity that was independent of terminal 2-O-sulfation. This correlated with the ability to dimerize FGF2 in an apparently cooperative manner. This data suggests that potent mitogenic signaling results from heparin-mediated trans-dimerization of FGF2, consistent with the asymmetric model of ternary complex formation. We propose that, depending on saccharide structure, there are different architectures and modes of ternary complex assembly that differ in stability and/or efficiency of transmembrane signaling.

Heparin sequencing.

Heparin is a highly sulfated glycosaminoglycan widely used as an anticoagulant. Modifications in its relatively uniform structure appear to be key to its recognition and modulation of serine proteases, growth factors, chemokines, and extracellular proteins, as has been most clearly demonstrated in the antithrombin binding site. We sequenced the major oligosaccharides released from mastocytoma heparin by partial nitrous acid using a highly sensitive technique tailored for sequencing of metabolically radiolabeled heparin. It utilizes partial nitrous acid cleavage to allow simultaneous sequencing of the internal components of the oligosaccharide under investigation by specific lysosomal exoenzymes. Sequencing revealed that although the majority of the heparin disaccharides are N-, 2-O-, and 6-O-sulfated, the less sulfated disaccharides (lacking 2-O- or 6-O-sulfates) seem to be spaced out along the chain. The technique may be particularly useful for characterizing heparin from novel sources, such as the glial progenitor cells and Ascidia, as well as for sequencing protein binding sites.