Grafted synthetic polypeptides hold appeal for extending the range of biophysical properties achievable in synthetic extracellular matrix (ECM) hydrogels. Here, N-carboxyanhydride polypeptide, poly(gamma-propargyl-L-glutamate) (PPLG) macromers were generated by fully grafting the "clickable" side chains with mixtures of short polyethylene glycol (PEG) chains terminated with inert (-OH) or reactive (maleimide and/or norbonene) groups, then reacting a fraction of these groups with an RGD cell attachment motif. A panel of synthetic hydrogels was then created by cross-linking the PPLG macromers with a 4-arm PEG star molecule. Compared to well-established PEG-only hydrogels, gels containing PPLG exhibited dramatically less dependence on swelling as a function of cross-link density. Further, PPLG-containing gels, which retain an a-helical chain conformation, were more effective than standard PEG gels in fostering attachment of a human mesenchymal stem cell (hMSC) line for a given concentration of RGD in the gel. These favorable properties of PPLG-containing PEG hydrogels suggest they may find broad use in synthetic ECM.