Growth factor (GF)
signaling is a key determinant of stem cell
fate. Interactions of GFs with their receptors are often mediated
by heparan sulfate proteoglycans (HSPGs). Here, we report a cell surface
engineering strategy that exploits the function of HSPGs to promote
differentiation in embryonic stem cells (ESCs). We have generated
synthetic neoproteoglycans (neoPGs) with affinity for the fibroblast
growth factor 2 (FGF2) and introduced them into plasma membranes of
ESCs deficient in HS biosynthesis. There, the neoPGs assumed the function
of native HSPGs, rescued FGF2-mediated kinase activity, and promoted
neural specification. This glycocalyx remodeling strategy is versatile
and may be applicable to other types of differentiation.
The cellular glycocalyx controls many of the crucial signaling pathways involved in cellular development. Synthetic materials that can mimic the multivalency and three-dimensional architecture of native glycans serve as important tools for deciphering and exploiting the roles of these glycans. Here we describe a chemical approach for the engineering of growth-factor interactions at the surfaces of stem cells using synthetic glycomimetic materials, with an eye towards promoting their commitment towards specific cell lineages with therapeutic potential.
Heparan sulfate glycosaminoglycans (HS GAGs) attached to proteoglycans harbor high affinity binding sites for various growth factors (GFs) and direct their organization and activity across the cell-matrix interface. Here, we describe a mild and efficient method for generating HS-protein conjugates. The two-step process utilizes a "copper-free click" coupling between differentially sulfated heparinoids primed at their reducing end with an azide handle and a bovine serum albumin protein modified with complementary cyclooctyne functionality. When adsorbed on tissue culture substrates, the glycoconjugates served as extracellular matrix proteoglycan models with the ability to sequester FGF2 and influence mesenchymal stem cell proliferation based on the structure of their HS GAG component.
Extracellular glycans, such as glycosaminoglycans (GAGs), provide an essential regulatory component during the development and maintenance of tissues. GAGs, which harbor binding sites for a range of growth factors (GFs) and other morphogens, help establish gradients of these molecules in the extracellular matrix (ECM) and promote the formation of active signaling complexes when presented at the cell surface. As such, GAGs have been pursued as biologically active components for the development of biomaterials for cell-based regenerative therapies. However, their structural complexity and compositional heterogeneity make establishing structure-function relationships for this class of glycans difficult. Here, a stem cell array platform is described, in which chemically modified heparan sulfate (HS) GAG polysaccharides are conjugated to a gelatin matrix and introduced into a polyacrylamide hydrogel network. This array allowed for direct analysis of HS contributions to the signaling via the FGF2-dependent mitogen activated protein kinase (MAPK) pathway in mouse embryonic stem cells. With the recent emergence of powerful synthetic and recombinant technologies to produce well-defined GAG structures, a platform for analyzing both growth factor binding and signaling in response to the presence of these biomolecules will provide a powerful tool for integrating glycans into biomaterials to advance their biological properties and applications.
Heparan sulfate glycosaminoglycans (HS GAGs) attached
to proteoglycans harbor high affinity binding sites for various growth factors
(GFs) and direct their organization and activity across the cell-matrix
interface. Here, we describe a mild and efficient method for generating HS-protein
conjugates. The two-step process utilizes a “copper-free” click coupling
between differentially sulfated heparinoids primed at their reducing end with
an azide handle and a bovine serum albumin protein modified with complementary cyclooctyne
functionality. When adsorbed on tissue culture substrates, the glycoconjugates
served as extracellular matrix proteoglycan models with the ability to
sequester FGF2 and influence mesenchymal stem cell proliferation based on the
structure of their HS GAG component.
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