M. Kayama

Transfection with pax6 Gene of Mouse Embryonic Stem Cells and Subsequent Cell Cloning Induced Retinal Neuron Progenitors, Including Retinal Ganglion Cell-Like Cells, in vitro

Objective: It is theoretically possible to induce various cell types, including retinal neurons, from embryonic stem cells (ESCs). pax6 regulates early events in eye development, including the generation of retinal ganglion cells (RGCs). We previously reported the successful induction of corneal epithelial cells from ESCs transfected with the pax6 gene. Here, we attempted to establish cloned RGC-like cells from ESCs transfected with the pax6 gene. Methods: Undifferentiated mouse ESCs were transfected with pax6 cDNA by electroporation, followed by selection with G418. We conducted limiting-dilution culture of pax6-transfected cells. We expanded the cloned pax6-transfected cells, which expressed nestin and musashi-1, for further characterization in culture media containing fibronectin. The cells were characterized using RT-PCR, immunostaining, electron microscopy, renal subcapsular transplantation assay and Ca imaging. Results: We obtained clonally expanding pax6-transfected cells, all of which were positive for six3, sonic hedgehog (shh), math5, brn3, thy1 and melanopsin, by using several ESCs. When transplanted into a mouse renal capsule, they differentiated into neurons with elongated axons, expressing βIII tubulin and neurofilament middle chain, and were free from teratoma development. Electron-microscopic examination showed neurotubules and neurofilaments in the axon-like processes of the cloned pax6-transfected cells. High KCl stimulation increased free Ca influx on Ca2+ imaging. Conclusions: ESCs were applicable for the induction of retinal progenitor cells, including RGC-like cells, by transfection with the pax6 gene and subsequent limiting-dilution culture. Cloned cell lines may be useful to analyze the requirements for retinal progenitor cell differentiation, and our study suggests the clinical application of this cell type.

Experimental transplantation of corneal epithelium-like cells induced by Pax6 gene transfection of mouse embryonic stem cells

Purpose: Corneal epithelial stem cells are deficient in cases of limbal disorders, leading to conjunctival epithelial ingrowth, vascularization, and eventually visual disturbance. We introduced the eye development-associated transcription factor pax6 to embryonic stem (ES) cells and tested whether pax6-transfected cells resembling purified corneal epithelial cells were applicable as a cell source for corneal transplantation. Methods: pax6 cDNA with green fluorescence protein was electrotransfected to ES cells and the cells were cultured with G418 for 14 days. They were characterized by reverse transcription-polymerase chain reaction and immunohistochemistry. The cells were transplanted onto experimentally damaged mouse corneas. Histologic reconstitution of the corneal epithelium was assessed. Results: pax6-transfected cells formed a monolayer of epithelium-like cells in vitro. They expressed cytokeratin12, a specific keratin of corneal epithelial cells, E-cadherin, and CD44, which are important adhesion molecules of corneal epithelial cells on the cell membrane. They accumulated to make a colony that gave a staining pattern of reticular configuration for cytokeratin 12, E-cadherin, and CD44. When the cells were transplanted onto damaged cornea, they have been kept alive on the cornea. Conclusions: The purified corneal epithelium-like cells derived from ES cells transfected with pax6 gene adapted to the injured cornea and were kept alive on it. These results suggested application of ES cell-derived corneal epithelial cells for treating corneal injuries.

Induction of corneal epithelium-like cells from cynomolgus monkey embryonic stem cells and their experimental transplantation to damaged cornea.

Purpose: We previously reported the successful transplantation of corneal epithelium-like cells derived from mouse embryonic stem (ES) cells onto injured mouse cornea. Here, we tested whether nonhuman primate ES cells have ability to differentiate into corneal epithelial cells and whether monkey ES cell-derived corneal epithelium-like cells were applicable for the experimental transplantation to damaged cornea. Methods: Monkey ES cells were cultivated on type IV collagen-coated dishes for various days to induce differentiation into corneal epithelium-like cells. The differentiation was evaluated by reverse transcription-polymerase chain reaction and immunostaining. The corneal epithelium-like cells were transplanted to the injured mouse cornea. Reconstitution of the corneal epithelium was evaluated by immunostaining. Results: The cells cultured on type IV collagen showed cobblestone-like appearance resembling epithelial cells. They expressed messenger RNA of pax6, p63, E-cadherin, CD44, proliferating cell nuclear antigen, keratin 3, and keratin 12. Protein expressions of pax6, keratin 3/12, p63, proliferating cell nuclear antigen, E-cadherin, and CD44 were confirmed by immunostaining. When the corneal epithelium-like cells were transplanted, they adhered to the corneal stroma, leading to formation of multiple cell layers. The grafted cells were stained with anti-human nuclear protein antibody, which cross-reacted with nuclei of monkey cells but not with those of mouse cells. They retained the expressions of keratin 3/12, E-cadherin, and CD44. Conclusions: We induced corneal epithelium-like cells from monkey ES cells with moderate efficiency. The cells were successfully transplanted onto the injured mouse cornea. This is the first demonstration that nonhuman primate ES cells were induced to differentiate into corneal epithelium-like cells, which were applicable for transplantation to an animal model of corneal injury.