ABSTRACT: Diverse cell types can be reprogrammed into pluripotent stem cells by ectopic expression of Oct4 (Pou5f1), Klf4, Sox3 and Myc. Many of these induced pluripotent stem cells (iPSCs) retain an epigenetic memory of their cellular origins and this in turn may bias their subsequent differentiation. Differentiated neurons are difficult to reprogram and there has not been a systematic side-by-side characterization of reprogramming efficiency or epigenetic memory across different neuronal subtypes. We have recently developed a new method for reprogramming retinal neurons and successfully reprogrammed rod photoreceptors from the murine retina. Here we extended our retinal reprogramming to cone photoreceptors, bipolar neurons, amacrine/horizontal cell interneurons and Müller glia at two different stages of development. We scored the efficiency of reprogramming across all 5 retinal cell types at each developmental stage and we measured retinal differentiation from each iPSC line using a quantitative standardized scoring system called STEM-RET. We discovered that the rod photoreceptors and bipolar neurons had the lowest reprogramming efficiency but iPSCs derived from rods and bipolar cells had the best retinal differentiation. Epigenetic memory was analyzed by characterizing DNA methylation and performing ChIP-seq for 8 histone marks, Brd4, PolII and CTCF. The epigenetic data were integrated with RNA-Seq data from each iPSC line. Retinal cell types with a greater epigenetic barrier to reprogramming (rods and bipolars) are more likely to retain epigenetic memory of their cellular origins. In addition, we identified biomarkers of iPSCs that are predictive of retinal differentiation. This work will have implications for selection of cell populations for cell based therapy and for using reprogramming of purified cell populations to advance our understanding of the role of the epigenome in normal differentiation.