Low-oxygen and knock-out serum maintain stemness in human retinal progenitor cells.

Using stem and progenitor cells to treat retinal disorders holds great promise. Using defined culture conditions to maintain the desires phenotype is of utmost clinical importance. We cultured human retinal progenitor cells (hRPCs) in different conditions: such as normoxia (20% oxygen), and hypoxia (5% oxygen) with and without knock-out serum replacement (KOSR) to evaluate its effect on these cells. KOSR is known nutrient supplement often used to replace bovine serum for culturing embryonic or pluripotent stem cells, especially those destined for clinical applications. The purpose of this study was to identify the impact of different environmental and chemical cues to determine if this alters the fate of these cells. Our results indicate that cells cultured with or without KOSR do not show significant differences in viability, but that the oxygen tension can significantly change their viability (higher in hypoxia than normoxia). However, cells with KOSR in hypoxia condition expressed significantly higher stemness markers such as C-myc and Oct4 (31.20% and 13.44% respectively) in comparison to hRPCs cultured in KOSR at normoxia (12.07% and 4.05%). Furthermore, levels of markers for retinal commitment such as rhodopsin were significantly lower in the KOSR supplemented cells in hypoxia culture compared to normoxia. KOSR is known to improve proliferation and maintain stemness of embryonic cells and our experiments suggest that hRPCs maintain their proliferation and stemness characteristics in hypoxia with KOSR supplement. Normoxia, however, results in mature cell marker expression, suggesting a profound effect of oxygen tension on these cells.

Construction and characterization of EGFP reporter plasmid harboring putative human RAX promoter for in vitro monitoring of retinal progenitor cells identity.

BACKGROUND: In retinal degenerative disease, progressive and debilitating conditions result in deterioration of retinal cells and visual loss. In human, retina lacks the inherent capacity for regeneration. Therefore, regeneration of retinal layer from human retinal progenitor cells (hRPCs) is a challenging task and restricted in vitro maintenance of hRPCs remains as the main hurdle. Retina and anterior neural fold homeobox gene (RAX) play critical roles in developing retina and maintenance of hRPCs. In this study, for the first time regulatory regions of human RAX gene with potential promoter activity were experimentally investigated. RESULTS: For this purpose, after in silico analysis of regulatory regions of human RAX gene, the expression of EGFP reporter derived by putative promoter sequences was first evaluated in 293 T cells and then in hRPCS derived from human embryonic stem cells. The candidate region (RAX-3258 bp) showed the highest EGFP expression in hRPCs. This reporter construct can be used for in vitro monitoring of hRPC identity and verification of an efficient culture medium for maintenance of these cells. CONCLUSIONS: Furthermore, our findings provide a platform for better insight into regulatory regions of human RAX gene and molecular mechanisms underlying its vital functions in retina development.

Human Retinal Progenitor Cells Derived Small Extracellular Vesicles Delay Retinal Degeneration: A Paradigm for Cell-free Therapy.

Retinal degeneration is a leading cause of irreversible vision impairment and blindness worldwide. Previous studies indicate that subretinal injection of human retinal progenitor cells (hRPCs) can delay the progression of retinal degeneration, preserve retinal function, and protect photoreceptor cells from death, albeit the mechanism is not well understood. In this study, small extracellular vesicles derived from hRPCs (hRPC-sEVs) were injected into the subretinal space of retinal dystrophic RCS rats. We find that hRPC-sEVs significantly preserve the function of retina and thickness of the outer nuclear layer (ONL), reduce the apoptosis of photoreceptors in the ONL, and suppress the inflammatory response in the retina of RCS rats. In vitro, we have shown that hRPC-sEV treatment could significantly reserve the low-glucose preconditioned apoptosis of photoreceptors and reduce the expression of pro-inflammatory cytokines in microglia. Pathway analysis predicted the target genes of hRPC-sEV microRNAs involved in inflammation related biological processes and significantly enriched in processes autophagy, signal release, regulation of neuron death, and cell cycle. Collectively, our study suggests that hRPC-sEVs might be a favorable agent to delay retinal degeneration and highlights as a new paradigm for cell-free therapy.

Interphotoreceptor matrix based biomaterial: Impact on human retinal progenitor cell attachment and differentiation.

While cell transplantation therapies show great promise as treatments for retinal degeneration, the challenge of low cell survival upon transplantation motivates exploration of materials that may serve as cell delivery vehicles and promote survival and differentiation. In this study, we explored the native matrix that surrounds the outer segments of photoreceptors and promotes their homeostasis, interphotoreceptor matrix (IPM), as a substrate for human retinal progenitor cells (hRPCs). Bovine IPM was characterized to determine its structure and biochemical composition, and processed to develop substrates for cells. Cell viability, morphology, proliferation and expression of photoreceptors marker genes were studied on IPM-based substrates in vitro. We explored different preparations of IPM as a scaffold. Lectin staining revealed that a distinct honeycomb structure of native IPM is lost during centrifugation to prepare a more concentrated suspension of matrix. Biochemical analysis of bovine IPM indicated presence of glycosaminoglycans and proteins. IPM mediated hRPC attachment and spreading with no signs of cytotoxicity. Cells proliferated more on native IPM substrates compared to IPM that was centrifuged to create a concentrated suspension. Cells cultured on IPM substrates expressed markers of photoreceptors: rhodopsin, NRL and ROM1. Together this data supports further exploration of IPM as a tool for retinal tissue engineering. © 2017 Wiley Periodicals, Inc. J Biomed Mater Res Part B: Appl Biomater, 106B: 891-899, 2018.