Publications

Keratocytes of the corneal stroma produce a transparent extracellular matrix required for vision. During wound-healing and in vitro, keratocytes proliferate, becoming fibroblastic, and lose biosynthesis of unique corneal matrix components. This study sought identification of cells in the corneal stroma capable of assuming a keratocyte phenotype after extensive proliferation. About 3% of freshly isolated bovine stromal cells exhibited clonal growth. In low-mitogen media, selected clonal cultures displayed dendritic morphology and expressed high levels of keratan sulfate, aldehyde dehydrogenase 3A1, and keratocan, molecular markers of keratocyte phenotype. In protein-free media, both primary keratocytes and selected clonal cells aggregated to form attachment-independent spheroids expressing elevated levels of those marker molecules. The selected clonal cells exhibited normal karyotype and underwent replicative senescence after 65-70 population doublings; however, they continued expression of keratocyte phenotypic markers throughout their replicative life span. The progenitor cells expressed elevated mRNA for several genes characteristic of stem cells and also for genes expressed during ocular development PAX6, Six2, and Six3. PAX6 protein was detected in the cultured progenitor cells and a small number of stromal cells in intact tissue but was absent in cultured keratocytes and fibroblasts. Cytometry demonstrated PAX6 protein in 4% of freshly isolated stromal cells. These results demonstrate the presence of a previously unrecognized population of PAX6-positive cells in adult corneal stroma that maintain the potential to assume a keratocyte phenotype even after extensive replication. The presence of such progenitor cells has implications for corneal biology and for cell-based therapies targeting corneal scarring.

Keratocytes of the corneal stroma secrete a specialized extracellular matrix essential for vision. These quiescent cells exhibit limited capacity for self-renewal and after cell division become fibroblastic, secreting nontransparent tissue. This study sought to identify progenitor cells for human keratocytes. Near the corneal limbus, stromal cells expressed ABCG2, a protein present in many adult stem cells. The ABCG2-expressing cell population was isolated as a side population (SP) by cell sorting after exposure to Hoechst 33342 dye. The SP cells exhibited clonal growth and continued to express ABCG2 and also PAX6, product of a homeobox gene not expressed in adult keratocytes. Cloned SP cells cultured in medium with fibroblast growth factor-2 lost ABCG2 and PAX6 expression and upregulated several molecular markers of keratocytes, including keratocan, aldehyde dehydrogenase 3A1, and keratan sulfate. Cloned corneal SP cells under chondrogenic conditions produced matrix staining with toluidine blue and expressed cartilage-specific markers: collagen II, cartilage oligomatrix protein, and aggrecan. Exposure of cloned SP cells to neurogenic culture medium upregulated mRNA and protein for glial fibrillary acidic protein, neurofilament protein, and beta-tubulin II. These results demonstrate the presence of a population of cells in the human corneal stroma expressing stem cell markers and exhibiting multipotent differentiation potential. These appear to be the first human cells identified with keratocyte progenitor potential. Further analysis of these cells will aid elucidation of molecular mechanisms of corneal development, differentiation, and wound healing. These cells may be a resource for bioengineering of corneal stroma and for cell-based therapeutics.

PURPOSE: To investigate the phenotype of fetal and adult human limbal cells cultured on human amniotic membrane and the ability of cultured adult human limbal cells to repair limbal stem cell deficiency in a rabbit model.

METHODS: Human adult and fetal limbal cells were isolated and cultured either on plastic plates or on human amniotic membrane. Connexin43, p63, and keratins 3 and 12 (K3 and K12) were detected by immunofluorescence and RT-PCR. Limbal stem cell deficiency was established in rabbits using chemical ablation and mechanical debridement. Cultured adult human limbal cells were transplanted onto rabbit corneas one month after injury, then fixed and imbedded in paraffin forty days later. Immunofluorescent staining of human-nuclear antigen, p63, K3, and connexin43 identified human-specific cells, progenitor cells, and differentiated corneal epithelial cells, respectively.

RESULTS: Adult and fetal cultured limbal cells appeared similar in morphology. RT-PCR results showed that cells cultured from the human adult and fetal limbal area expressed both p63 and K12, whereas cells from central adult epithelium expressed K12 only. Immunofluorescent staining showed that more cells were p63 positive when cultured on human amniotic membrane than on plastic. Double staining for p63 and connexin43 showed some p63-positive cells co-expressing connexin43. After transplantation of adult human limbal cells cultured on human amniotic membrane, injured rabbit corneas were completely reconstructed exhibiting epithelial integrity, improved corneal clarity, and little or no neovascularization. The majority of repopulated epithelial cells expressed anti-human nuclear antibody. Cells expressing p63 occurred throughout the new epithelium.

CONCLUSIONS: During healing, expression of p63 is not limited to epithelial stem cells but may also mark transient amplifying progenitor cells. Culture on human amniotic membrane suppresses differentiation of limbal epithelial cells and promotes the proliferation of p63 expressing cells. Amniotic membrane-cultured human limbal cells fully reconstructed rabbit corneas having limbal stem cell deficiency, with human cells providing most of the cells of the new epithelium. Expression p63 is distributed throughout the reconstructed tissue.

PURPOSE: To investigate the phenotype of fetal and adult human limbal cells cultured on human amniotic membrane and the ability of cultured adult human limbal cells to repair limbal stem cell deficiency in a rabbit model.

METHODS: Human adult and fetal limbal cells were isolated and cultured either on plastic plates or on human amniotic membrane. Connexin43, p63, and keratins 3 and 12 (K3 and K12) were detected by immunofluorescence and RT-PCR. Limbal stem cell deficiency was established in rabbits using chemical ablation and mechanical debridement. Cultured adult human limbal cells were transplanted onto rabbit corneas one month after injury, then fixed and imbedded in paraffin forty days later. Immunofluorescent staining of human-nuclear antigen, p63, K3, and connexin43 identified human-specific cells, progenitor cells, and differentiated corneal epithelial cells, respectively.

RESULTS: Adult and fetal cultured limbal cells appeared similar in morphology. RT-PCR results showed that cells cultured from the human adult and fetal limbal area expressed both p63 and K12, whereas cells from central adult epithelium expressed K12 only. Immunofluorescent staining showed that more cells were p63 positive when cultured on human amniotic membrane than on plastic. Double staining for p63 and connexin43 showed some p63-positive cells co-expressing connexin43. After transplantation of adult human limbal cells cultured on human amniotic membrane, injured rabbit corneas were completely reconstructed exhibiting epithelial integrity, improved corneal clarity, and little or no neovascularization. The majority of repopulated epithelial cells expressed anti-human nuclear antibody. Cells expressing p63 occurred throughout the new epithelium.

CONCLUSIONS: During healing, expression of p63 is not limited to epithelial stem cells but may also mark transient amplifying progenitor cells. Culture on human amniotic membrane suppresses differentiation of limbal epithelial cells and promotes the proliferation of p63 expressing cells. Amniotic membrane-cultured human limbal cells fully reconstructed rabbit corneas having limbal stem cell deficiency, with human cells providing most of the cells of the new epithelium. Expression p63 is distributed throughout the reconstructed tissue.