Effects of fibroblast origin and phenotype on the proliferative potential of limbal epithelial progenitor cells.

The current study investigates potential differences in fibroblast phenotype across the anterior segment of the human eye with the aim to understanding factors that support the regenerative function of human limbal epithelial progenitor cells (LEPs) during wound healing. Separate cultures of fibroblasts were established from the cornea, limbus and sclera by growth in serum-supplemented medium. The resulting cultures were examined for potential differences in morphology and growth rate, as well as expression of CD34, CD45, CD90, CD141, CD271, vimentin and α-smooth muscle actin (α-sma). Finally, cultures were examined for their ability to support the growth of LEPs. While all cultures grew at a similar rate, scleral cultures often contained larger and more irregularly shaped cells which stained positive for α-sma. Western blotting confirmed a gradient of α-sma expression with lowest levels in corneal cultures. All three cultures stained positively for CD90 and vimentin, and were negative for CD34, CD45, CD141 and CD271. Only limbal or corneal irradiated fibroblasts supported the establishment of LEP cultures. While LEP colony forming efficiency and prominent expression of ABCG2, C/EBPδ and p63 was similar with either limbal or corneal fibroblasts, limbal fibroblasts supported significantly better growth. These results indicate that scleral fibroblasts have an increased capacity for myofibroblast formation which appears to negatively impact on their ability to support LEP growth. Superior growth of LEPs in the presence of limbal fibroblasts indicates a role for limbal fibroblasts in promoting the proliferation of limbal epithelium during wound healing.

PHEMA hydrogels modified through the grafting of phosphate groups by ATRP support the attachment and growth of human corneal epithelial cells.

Converting the surface of poly(2-hydroxyethyl methacrylate) (PHEMA) hydrogel into a cell-adhesive surface has been successfully achieved through a method based on atom transfer radical polymerization (ATRP) grafting. Following activation of the surface hydroxyl groups of PHEMA by bromination, surface-initiated ATRP of mono(2-methacryloyloxyethyl) phosphate (MMEP) was conducted in a methanol-water system with Cu(I)Br as catalyst at room temperature. The conversion of PHEMA hydroxyl groups to brominated isobutyryl groups and the occurrence of grafting of PMMEP were confirmed by infrared and X-ray photoelectron spectroscopies. Cell attachment experiments were conducted by culturing human corneal limbal epithelial cells on the PMMEP-grafted PHEMA, and on unmodified PHEMA and tissue culture plastic for comparison. The results showed that the grafted PMMEP was homogeneously distributed, and the phosphate groups appeared to significantly promote the attachment, spreading and growth of cells, at a level comparable to the tissue culture plastic.

Bombyx mori silk fibroin membranes as potential substrata for epithelial constructs used in the management of ocular surface disorders.

Membranes were prepared from fibroin, a protein isolated from the domesticated silkworm (Bombyx mori) silk, and evaluated as a potential substratum for corneal limbal epithelial cells. These membranes (i.e., B. mori silk fibroin [BMSF] membranes) were cast from dialyzed solutions of fibroin protein (4% w/v) dispensed into 35-mm-diameter culture dishes and dried at room temperature (23-24 degrees C). The resulting material was transparent, easy to handle, and supported levels of human limbal epithelial (HLE) cell growth comparable to that observed on tissue culture plastic. Remarkably, these results were obtained utilizing a commercial serum-free medium (CnT-20) designed for the ex vivo expansion of corneal epithelial progenitor cells. The potential benefits of serum proteins on this culture system were examined through addition of fetal bovine serum (FBS) either to fibroin stocks prior to membrane casting or by supplementation of the CnT-20 medium. Membranes cast in the presence of FBS displayed increasing opacity and induced little change in HLE growth. Supplementation of CnT-20 medium with FBS deterred cell growth on all substrata, including tissue culture plastic control substrata. The remarkable properties of BMSF membranes demonstrated under serum-free conditions warrant investigation of this material as a substratum in the creation of tissue-engineered constructs for the restoration of diseased or damaged ocular surface.

Vitronectin supports migratory responses of corneal epithelial cells to substrate bound IGF-I and HGF, and facilitates serum-free cultivation.

Vitronectin (VN) is a multi-functional glycoprotein best known for its effects on cell attachment and spreading, but has more recently been shown to mediate cellular responses to growth factors. The presence of VN within the tear film and expression of required receptors (alpha v integrins) on corneal epithelial cells suggests the potential for a similar role within the ocular surface. Thus we have studied the ability of VN to alter the metabolic (MTT assay) and migratory (trans-membrane migration) responses of corneal epithelial cells to growth factors associated with the ocular surface including epidermal growth factor (EGF), hepatocyte growth factor (HGF), keratinocyte growth factor (KGF) and insulin-like growth factor-I (IGF-I). Our hypothesis was that culture surfaces coated with VN might selectively facilitate responses to growth factors which are known to bind VN including EGF, IGF-I (via IGF binding protein) and HGF. Metabolic responses were observed towards each growth factor when applied to the culture medium, but not towards culture plastic pre-treated with VN and, or growth factors. Optimal metabolic responses were observed towards IGF-I applied in conjunction with EGF. Migration through porous polycarbonate membrane was significantly increased when the substrate had been pre-coated with VN and IGF-I (applied in conjunction with IGFBP-3) or VN and HGF. This finding is consistent with the ability of IGF-I (via an IGFBP) and HGF to form complexes with VN and suggests that integrin/growth factor receptor co-activation is required for corneal epithelial cell migration. In further studies, VN applied in conjunction with IGF-I, IGFBP-3 and EGF (both to the culture plastic and in the culture medium) was found to support the establishment and serial propagation of limbal-corneal epithelial cell cultures in the absence of serum, but irradiated 3T3 cells (i3T3) were still necessary for culture expansion. Immunocytochemistry of resulting cultures for keratin 3 and p63 revealed a similar phenotype to those established under current best-practice conditions (i3T3, foetal bovine serum, EGF and insulin). In conclusion, our novel findings suggest a role for VN-growth factor complexes in stimulating corneal epithelial migration within the provisional wound bed and demonstrate that VN-growth factors interactions can be exploited to enable manufacture of bioengineered ocular surface tissue under serum-free conditions.