Enhanced survival of neural cells embedded in hydrogels composed of collagen and laminin-derived cell adhesive peptide

To develop biomaterials that serve to improve the survival of neural cells transplanted into central nervous tissues, type I collagen-based hydrogels were prepared as a cell carrier. The hydrogels were modified with a laminin-derived peptide that is known to have an affinity for alpha3beta1 integrin, to transduce antiapoptotic signaling in embedded cells. For the modification of collagen, the peptide was fused to the N- or C-terminus, or both termini of a collagen-binding polypeptide domain by means of recombinant DNA technology. The chimeric proteins were characterized by polyacrylamide gel electrophoresis and circular dichroism spectroscopy, while binding of chimeric proteins to collagencoated substrates was verified by surface plasmon resonance analysis under physiological conditions. Cell culture assays revealed that the adhesion of neurosphere-forming cells to collagen-coated polystyrene surfaces was significantly promoted by the incorporation of the chimeric proteins in a peptide-density dependent manner. The live/dead assays for cells cultured for 24 or 48 h in the hydrogels revealed that peptide incorporation improved the survival of cells embedded in collagen hydrogels. These results suggest that collagen hydrogel containing the laminin-derived peptide provides microenvironments suitable for the survival of neural cells.