Differences in sphere-forming cells from keratoconic and normal corneal tissue: Implications for keratoconus pathogenesis.

Keratoconus is primarily an anterior corneal disorder of unclear aetiology. Stem cells may play a role in the perpetuation of keratoconus, although this has yet to be definitively established. Sphere-forming cells from normal human donor corneas have previously been shown to be a heterogenous mix of epithelial, stromal, stem and progenitor cell components which have potential for treatment of corneal dystrophies. Our work set out to isolate and characterise sphere-forming cells from human keratoconic tissue. Keratoconic donor corneas were successfully used to culture sphere-forming cells in vitro. Time lapse imaging of these spheres on a collagen surface over 8 days revealed keratoconic spheres lack the ability to maintain a central core and have diminished ability to repopulate the surface. Immunocytochemistry showed positive labelling for the stem cell marker 'Adenosine triphosphate-binding cassette sub-family B member 5 (ABCB5)' indicating stem cell retention and the myofibroblast marker alpha smooth muscle actin indicating wound repair while droplet digital Polymerase Chain Reaction confirmed an increase in expression of stem and stromal cell markers in keratoconic spheres compared to spheres cultured from normal donors at day 7 post-placement. Keratoconic sphere-forming cells showed a diminished repopulation ability, a faster wound healing response and lack of central core retention. These results suggest stem cells in keratoconus may be in an elevated state of wound repair and unable to respond appropriately to further injury in corneal maintenance. Sphere forming cell populations in keratoconus appear to be different to those isolated from normal corneas and this may be an important consideration in unearthing keratoconus aetiology.

Sphere-forming cells from peripheral cornea demonstrate a wound-healing response to injury.

The cornea is the initial refractive interface of the eye. Its transparency is critical for clear vision and is maintained by stem cells which also act to repair injury inflicted by external insults, such as chemical and thermal burns. Damage to the epithelium compromises its clarity and can reduce or eliminate the stem cell population, diminishing the ability for self-repair. This condition has been termed "limbal stem cell deficiency"; severe cases can lead to corneal blindness. Sphere-forming cells isolated from peripheral cornea are a potential source of stem and progenitor cells for corneal repair. When provided with appropriate substrate, these spheres have the ability to adhere and for cells to migrate outwards akin to that of their natural environment. Direct compression injury and remote scratch injury experiments were conducted on the sphere cells to gauge their wound healing capacity. Measures of proliferation, differentiation, and migration were assessed by immunohistochemical detection of EdU incorporation, α-smooth muscle actin expression and confocal image analysis, respectively. Both modes of injury were observed to draw responses from the spheres indicating wound healing processes. Direct wounding induced a rapid, but transient increase in expression of α-SMA, a marker of corneal myofibroblasts, followed by a proliferative and increasing migratory response. The spheres were observed to respond to remote injury as entire units, with no directional response seen for targeted repair over the scratch injury area. These results give strength to the future use of these peripheral corneal spheres as transplantable units for the regeneration of corneal tissue.

Cells from the adult corneal stroma can be reprogrammed to a neuron-like cell using exogenous growth factors.

Cells thought to be stem cells isolated from the cornea of the eye have been shown to exhibit neurogenic potential. We set out to uncover the identity and location of these cells within the cornea and to elucidate their neuronal protein and gene expression profile during the process of switching to a neuron-like cell. Here we report that every cell of the adult human and rat corneal stroma is capable of differentiating into a neuron-like cell when treated with neurogenic differentiation specifying growth factors. Furthermore, the expression of genes regulating neurogenesis and mature neuronal structure and function was increased. The switch from a corneal stromal cell to a neuron-like cell was also shown to occur in vivo in intact corneas of living rats. Our results clearly indicate that lineage specifying growth factors can affect changes in the protein and gene expression profiles of adult cells, suggesting that possibly many adult cell populations can be made to switch into another type of mature cell by simply modifying the growth factor environment.

Sphere-forming cells from peripheral cornea demonstrate polarity and directed cell migration.

Sphere-forming cells from peripheral cornea represent a potential source of progenitor cells for treatment of corneal degenerative diseases. Control of cellular repopulation on transplantable substrates is important to prevent uncontrolled growth in unfavourable directions. The coordination of cellular outgrowth may be in response to environmental cues and/or cellular signals from other spheres. To investigate this, cell migration patterns were observed following placement of spheres on an adhesive surface. Human peripheral corneal cells were maintained using a sphere-forming assay and their behaviour on collagen substrate recorded by time-lapse imaging. Immunocytochemistry and proliferation assays were used to detect protein expression and cell division. Proliferation assays showed that spheres formed by a combination of cell division and aggregation. Cell division continued within spheres for up to 4 months and was up-regulated when exposed to differentiation medium and collagen substrate. The spheres expressed both epithelial and stromal cell markers. When exposed to collagen; (1) 25% of the spheres showed spontaneous polarised outgrowth. (2) One sphere initially showed polarised outgrowth followed by collective migration with discrete morphological changes to form leading and trailing compartments. (3) A sphere which did not show polarised outgrowth was also capable of collective migration using cell protrusion and retraction. (4) Active recruitment of cells into spheres was observed. (5) Placement of spheres in close proximity led to production of a cell exclusion area adjacent to spheres. Thus peripheral corneal cell spheres are dynamic entities capable of developing polarity and modifying migration in response to their environment.

Efficacy and safety assessment of a novel ultraviolet C device for treating corneal bacterial infections.

BACKGROUND: A prototype solid-state Ultraviolet-C (UVC) LED device may be useful in the treatment of corneal microbial infections, as UVC is commonly used for eradicating bacteria, fungi and viruses in other settings. This study assessed the efficacy of 265 nm UVC from this LED, on four different bacterial strains, and investigated the consequences of corresponding exposures on human corneal epithelial cells in vitro. METHODS: Agar plate lawns of Staphylococcus aureus, Escherichia coli, Pseudomonas aeruginosa and Streptococcus pyogenes were exposed to a 4.5 mm diameter 265 nm UVC beam at a fixed intensity and distance, for 30, 5, 4, 2 and 1 seconds. Growth inhibition was assessed with a BioRad Gel imager, and the diameter of lucent areas of bacterial inhibition recorded. Human corneal epithelial cells cultured on glass cover-slips were exposed to corresponding doses of UVC from the same device. Live/dead staining was performed and the results quantified. RESULTS: There was 100% inhibition of growth for all bacteria tested, at all exposure times. A 30-second exposure of human corneal epithelium to UVC gave no statistically significant decrease (P = 0.877) in the ratio of live to dead cells when compared to control cultures. CONCLUSION: The results confirmed that a 1 second exposure to germicidal UVC from this LED source was sufficient to inhibit microbial proliferation in the four bacterial strains tested in vitro. The literature suggests UVC at this dose could potentially be beneficial in treating corneal surface infections, without causing significant adverse effects, supported by our findings in human corneal epithelium exposed to UVC.

Comparative prediction schemes using conventional and advanced statistical analysis to predict microbial water quality in runoff from manured fields.

Accurate estimations of indicator microorganisms' concentrations are necessary to properly monitor water quality and manage contamination from agricultural land runoffs. In this study, Artificial Neural Networks (ANNs) and Multiple Regression Analysis (MRA) statistical methods were compared for accuracy in the prediction of manure-borne microorganisms' concentrations in runoffs from agricultural plots (0.75 m × 2 m) treated with cattle or swine manure. Field rainfall simulation tests were initiated on days 4, 32, 62, 123, and 354 between June 2002 and May 2003. Each rainfall event produced 35 mm rainfall for 30 min at the intensity of 70 mm hr(-1) at 24-intervals. Concentrations of microbial indicators were correlated with hydrological and environmental water quality parameters including water runoff, erosion, air temperature, relative humidity, solar radiation, pH, electric conductivity (EC) and turbidity to determine their impacts on microbial fate and transport. ANNs demonstrated a better ability to model the nonlinearity of land application of manure to ensure the safety of agricultural water environments.

Sphere-forming corneal cells repopulate dystrophic keratoconic stroma: Implications for potential therapy.

BACKGROUND: Keratoconus is a degenerative corneal disease characterised by aberrant cell behaviour and loss of matrix that can result in vision loss. Cells extracted from peripheral corneas can form stem cell-enriched spheres, which have shown the potential to repopulate the normal peripheral corneal stroma in vitro upon sphere implantation but have not been previously studied in keratoconic tissue. AIM: To investigate the therapeutic potential of stem cell-enriched spheres formed from extracted peripheral human corneal cells when introduced to keratoconic tissue. METHODS: Stem cell-enriched spheres were formed from extracts of normal cadaveric human peripheral corneal cells. These spheres were implanted into incisions created in full thickness and onto the surface of 10 µm thin sections of keratoconic and normal stromal tissues in vitro. Tissue sections were used to maximise use of limited keratoconic tissue available for research. Living cells were stained with Calcein-AM and visualised with stereo and fluorescence microscopy to assess survival and behaviours between the time of implantation day 0 and 14 d (D14) from implantation. Sphere cells in implanted tissues were characterised for stem cell and differentiation markers using immunohistochemistry and droplet digital PCR to assess the potential implications of these characteristics in the use of spheres in keratoconus treatment. RESULTS: Spheres were successfully implanted into full-thickness central corneal tissue and onto the surface of 10 µm thin en face tissue sections. No observable differences were seen in sphere migration, proliferation or differentiation in keratoconic tissue compared to normal between day 0 and D14. Spheres stained positively with Calcein-AM up to D14. Cell migration increased from day 0 to D14, occurring radially in three dimensions from the sphere and in alignment with tissue edges. Cell proliferation marker, EdU, was detected at day 10. Implanted spheres stained positively for putative stem cell markers ∆Np63α and ABCB5, while ABCG2, ABCB5, ∆Np63 and p63α were detectable by droplet digital PCR up to D14. Double immunolabelling revealed absence of ABCB5 staining in migrated cells but positive staining of alpha smooth muscle actin (myofibroblast marker) in some migrated cells. Droplet digital PCR showed similar expression patterns of differentiation markers but a reduction in stem cell markers between normal and keratoconic tissue with an increase in stromal cell markers and a reduction in epithelial cell markers, indicating an appropriate response to repopulating diseased tissue. CONCLUSION: Cells from implanted stem cell-enriched spheres can repopulate a keratoconic corneal stromal surface in a directed manner and exhibit migratory stromal cell phenotypes.

Implantation of Human Peripheral Corneal Spheres into Cadaveric Human Corneal Tissue.

Stem and progenitor cells isolated from human limbal tissue can be cultured in vitro as spheres. These spheres have potential for use as transplantable elements for the repopulation of corneal tissue ( Mathan et al., 2016 ). Herein we describe the detailed protocol for the implantation of human corneal spheres into cadaveric human corneal tissue. This protocol describes the procedure for sphere formation and culture, preparation of tissue for sphere implantation, corneal limbus microsurgery and sphere implantation.

Sphere-forming cells from peripheral cornea demonstrate the ability to repopulate the ocular surface.

BACKGROUND: The limbus forms the outer rim of the cornea at the corneoscleral junction and harbours a population of stem cells for corneal maintenance. Injuries to the limbus, through disease or accidents such as chemical injuries or burns, may lead to significant visual impairment due to depletion of the native stem cells of the tissue. METHODS: Sphere-forming cells were isolated from peripheral cornea for potential use as transplantable elements for limbal stem cell repopulation and limbal reconstruction. Immunocytochemistry, live cell imaging and quantitative PCR were used to characterize spheres and elucidate activity post implantation into human cadaveric corneal tissue. RESULTS: Spheres stained positively for stem cell markers ∆NP63α, ABCG2 and ABCB5 as well as the basal limbal marker and putative niche marker, notch 1. In addition, spheres also stained positively for markers of corneal cells, vimentin, keratin 3, keratocan and laminin, indicating a heterogeneous mix of stromal and epithelial-origin cells. Upon implantation into decellularized corneoscleral tissue, 3D, polarized and radially orientated cell migration with cell proliferation was observed. Cells migrated out from the spheres and repopulated the entire corneal surface over 14 days. Post-implantation analysis revealed qualitative evidence of stem, stromal and epithelial cell markers while quantitative PCR showed a quantitative reduction in keratocan and laminin expression indicative of an enhanced progenitor cell response. Proliferation, quantified by PCNA expression, significantly increased at 4 days subsequently followed by a decrease at day 7 post implantation. CONCLUSION: These observations suggest great promise for the potential of peripheral corneal spheres as transplantable units for corneal repair, targeting ocular surface regeneration and stem cell repopulation.

Improved corneal wound healing through modulation of gap junction communication using connexin43-specific antisense oligodeoxynucleotides.

PURPOSE: Gap junctions play a major role in corneal wound healing. This study used reproducible models of corneal wound healing to evaluate the effect of a gap junction channel modulator, connexin43 (Cx43) antisense oligodeoxynucleotides (AsODN), on corneal healing dynamics. METHODS: A mechanical scrape wound model was used to evaluate Cx43 AsODN penetration and initial wound reepithelialization 12 hours postsurgery. Thereafter, detailed analyses of corneal edema, inflammation, and healing were performed in an excimer laser surface ablation model. In vivo confocal microscopy determined clinical parameters (edema, haze) and cellular changes (stromal hypercellularity, reepithelialization), whereas histology and immunohistochemistry were used to quantify stromal edema, inflammation, and reepithelialization. RESULTS: Cx43 AsODN penetrated through the hydrophilic stroma where the epithelium had been removed and accumulated in the basal epithelium close to the wound edge. Twelve hours after scrape wounding, Cx43 AsODN-treated eyes showed a significant reduction in wound area compared with the vehicle alone (1.59±0.37 and 2.29±0.58 mm2, respectively, P<0.01). After excimer laser ablation, stromal edema and inflammation were reduced, with endothelial structures being clearly visible, and reepithelialization rates were again increased in Cx43 AsODN-treated eyes. Histologic analysis confirmed reduced edema in the central wound site and at the periphery of treated corneas (P<0.05), whereas immunohistochemistry showed lower Cx43 levels (P<0.05), reduced myofibroblast activation, and improved epithelial basal lamina deposition in antisense-treated wounds (P<0.01). CONCLUSIONS: Application of Cx43 AsODN to the cornea reduces stromal edema and inflammation, promoting faster wound closure and a more uniform repair of the epithelial basal lamina after laser ablation.

Comparison of stem cell properties in cell populations isolated from human central and limbal corneal epithelium.

PURPOSE: The limbus of the cornea is said to be the niche for limbal stem cells (LSCs) and the primary source of corneal epithelial maintenance. Previously, we aimed to have shown that central human epithelial cells are capable of corneal regeneration after wounding. In this study, we aimed to investigate whether central epithelial cells in human corneas have LSC properties. METHODS: Human corneal epithelial cells were separated from the central cornea and the limbus. Isolated cells were collected for sphere-forming assay, and spheres formed subsequently were analyzed using immunohistochemistry. Fluorescence-activated cell sorting (FACS) was also used to analyze epithelial cells from central cornea, limbal rim, older donors, younger donors, and dissociated spheres. These analyses were based on cell size and Hoechst 33342 dye efflux ability, and side populations and non-side populations were isolated for colony growth measurement and sphere-forming assay. RESULTS: Human central and limbal epithelial cells were capable of forming spheres, in a 1:2 ratio, that were positive for p63 immunolabeling. In FACS, central and limbal epithelial cells showed no significant difference in cell size and dye efflux ability. There were almost 10 times more large cells with good dye efflux ability from younger donors than from older donors, and the gated side population showed more than 4 times faster rate of colony growth than the non-side population. Dissociated sphere cells, however, did not follow a similar pattern to tissue-derived cells using FACS analysis. In these, there were more than twice as many large cells than small cells with good dye efflux ability. CONCLUSIONS: Both limbal and central epithelial cells are capable of forming spheres in cultures that have stem cell properties. Central and limbal epithelial cells cannot be differentiated using FACS, but younger donor tissues give rise to greater numbers of large cells with high dye efflux. Therefore, results indicate that human central corneal epithelium contains cells with stem/progenitor properties, and these stem properties decline with age.