Human amniotic fluid-derived stem cells (AFSCs) are pluripotent fetal cells capable of differentiating into multiple lineages, including representatives of the three embryonic germ layers. Stem cells which derived from human amniotic fluid may become a more suitable source of stem cells in regenerative medicine and tissue engineering. However, stem cell characteristics, such as proper differentiation and maintenance of pluripotency, are regulated not only by the stem cells themselves but also by their microenvironment. On the other hand, the stem cell fates of pluripotency and differentiation can influence by biological cues (i.e. extracellular matrix (ECM)) and physical cues (i.e. elasticity) of cell culture biomaterials. Here we investigated the maintenance of pluripotency and differentiation ability of AFSCs cultured on poly(vinylalcohol-co-itaconic acid), PVA-IA films grafted with several ECM-derived oligopeptides and combined with cyclic RGD having different elasticity. AFSCs cultured on soft PVA-IA films (19.6 kPa) grafted with ECM-derived oligopeptides showed high pluripotency, as assessed by the pluripotent gene expression (Oct4, Sox2, and Naong). AFSCs grow on stiff PVA-IA films (30.4 kPa) grafted with the combination of oligopeptides derived from collagen type I (oligoCOL) and cyclic RGD peptide showed higher pluripotency than that grafted with oligoCOL. Surprisingly, AFSCs cultured on PVA-IA films showed higher pluripotency also expressed higher level of early differentiation markers for three germ layers (Nestin, Runx2, Sox17) in expansion medium. This result suggests that AFSCs are heterogenous and that this population contains highly pluripotent stem cells and stem cells that can be easily differentiated. It is suggested that physical cues such as stiffness of culture biomaterials and biological cues such as ECM-derived peptides can guide pluripotency and differentiation ability of stem cells.