The Impact of Chain Length and Flexibility in the
Interaction between Sulfated Alginates and HGF and FGF‑2
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Abstract
Alginate
is a promising polysaccharide for use in biomaterials
as it is biologically inert. One way to functionalize alginate is
by chemical sulfation to emulate sulfated glycosaminoglycans, which
interact with a variety of proteins critical for tissue development
and homeostasis. In the present work we studied the impact of chain
length and flexibility of sulfated alginates for interactions with
FGF-2 and HGF. Both growth factors interact with defined sequences
of heparan sulfate (HS) at the cell surface or in the extracellular
matrix. Whereas FGF-2 interacts with a pentasaccharide sequence containing
a critical 2-O-sulfated iduronic acid, HGF has been suggested to require
a highly sulfated HS/heparin octasaccharide. Here, oligosaccharides
of alternating mannuronic and guluronic acid (MG) were sulfated and
assessed by their relative efficacy at releasing growth factor bound
to the surface of myeloma cells. 8-mers of sulfated MG (SMG) alginate
showed significant HGF release compared to shorter fragments, while
the maximum efficacy was achieved at a chain length average of 14
monosaccharides. FGF-2 release required a higher concentration of
the SMG fragments, and the 14-mer was less potent compared to an equally
sulfated high-molecular weight SMG. Sulfated mannuronan (SM) was subjected
to periodate oxidation to increase chain flexibility. To assess the
change in flexibility, the persistence length was estimated by SEC-MALLS
analysis and the Bohdanecky approach to the worm-like chain model.
A high degree of oxidation of SM resulted in approximately twice as
potent HGF release compared to the nonoxidized SM alginate. The release
of FGF-2 also increased with the degree of oxidation, but to a lower
degree compared to that of HGF. It was found that the SM alginates
were more efficient at releasing FGF-2 than the SMG alginates, indicating
a greater dependence on monosaccharide identity and charge orientation
over chain flexibility and charge density