Molecular
Vision 2012; 18:1505-1515
<http://www.molvis.org/molvis/v18/a156>
Received 26 March 2012 | Accepted 4 June 2012 | Published 7 June
2012
Kazuhisa Miyamoto,1 Takeshi Kobayashi,2,3 Yasuhito Hayashi,2 Yuan Zhang,1 Yuko Hara,1 Masakatsu Higashine,1 Atsushi Shiraishi,1,3 Yuichi Ohashi1,4
1Department of Ophthalmology, Ehime University Graduate School of Medicine, Shitsukawa, Toon, Ehime, Japan; 2Department of Ophthalmology and Regenerative Medicine, Ehime University Graduate School of Medicine, Shitsukawa, Toon, Ehime, Japan; 3Department of Stem Cell Biology, Ehime University Graduate School of Medicine, Shitsukawa, Toon, Ehime, Japan; 4Department of Infectious Diseases, Ehime University Graduate School of Medicine, Shitsukawa, Toon, Ehime, Japan
Correspondence to: Atsushi Shiraishi, M.D., Ph.D., Department of Ophthalmology, Ehime University School of Medicine, Shizukawa, Toon, Ehime, JAPAN, 791-0295; Phone: 81-89-960-5361; FAX: 81-89-960-5364 email: shiraia@m.ehime-u.ac.jp
Purpose: To study the roles played by stem cell factor (SCF) and SCF receptor c-kit in wound healing of corneal epithelial cells.
Methods: A 2 mm corneal epithelial wound was made in control (WBB6F1+/+), SCF (Sl/Sld)-, and c-kit (W/Wv) mutant mice, and the speed of wound healing, 5-bromo-2’-deoxyuridine (BrdU) incorporation, and scanning electron microscopic (SEM) morphology of the corneas were examined. The incorporation of BrdU and the degree of cell attachment in cultured mouse corneal epithelial cells (MCECs) isolated from WBB6F1+/+, Sl/Sld, and W/Wv mice were examined. Cultured immortalized human corneal epithelial cells (HCECs) were examined by a cell attachment assay after their exposure to anti-SCF antibodies, tyrosine kinase inhibitor (genistein), and competitive Arg-Gly-Asp (RGD) peptide, as well as on cultures treated with extracellular matrix.
Results: The speed of corneal wound healing was slower in Sl/Sld and W/Wv mice than in controls (p<0.01) and the speed of healing in Sl/Sld mice recovered after topical application of SCF (8 ng/ml). No significant difference was found in the BrdU incorporation assay either in vivo or in vitro. Loosened epithelial cells were detected at wound margins in W/Wv mice by SEM. The cell attachment rate was increased by 157% in cells from WBB6F1+/+ and 252% in Sl/Sld MCECs by recombinant mouse SCF; however, no significant difference was found in W/Wv MCECs. Anti-SCF antibodies (Ab), genistein, and RGD peptide reduced the percentage of attached HCECs. Anti-SCF Ab inhibited the attachment of HCECs on fibronectin, laminin, or type IV collagen coated dishes.
Conclusions: These findings indicate that the SCF/c-kit system may play a role in corneal wound healing through epithelial cell attachment.
Stem cell factor (SCF), also called c-kit ligand, steel factor, and mast cell growth factor, is composed of 164 amino acids and has a molecular weight of 30 kDa. It exists in soluble and membrane-bound forms [1-4]. SCF signals are transmitted by the c-kit receptor, which belongs to the same subfamily of tyrosine kinases receptors as platelet-derived growth factor (PDGF) and granulocyte macrophage colony-stimulating factor (GM-CSF) [2-5]. c-kit has an immunoglobulin-like structure in the extracellular domain and a tyrosine kinase-like structure in the cytoplasmic domain. The tyrosine kinase activity of this receptor is tightly regulated by SCF and is known to play a crucial role in signal transduction pathways involved in the growth and differentiation of various cells [6-10]. c-kit is distributed in such tissues as bone marrow, spleen, thymus, skin, and testis, while SCF is expressed in placental tissue, bone marrow stromal cells, venous endothelial cells, fibroblasts, and Sertoli cells [11-13]. The SCF/c-kit system functions mainly in the stimulation and maturation of myeloid, erythroid, and lymphoid progenitors, and in the differentiation and growth of melanocytes, germ cells, and mast cells [6,9,10,14-16].
Recent studies have demonstrated that epithelial cells express SCF and/or c-kit and the SCF/c-kit system has important functional roles in epithelial cells. Thus, ovarian surface epithelial cells express SCF and c-kit, suggesting that they are involved in normal ovarian surface epithelial biology as well as ovarian cancer [17]. In the skin, SCF and c-kit are expressed in mast cells, melanocytes, and epithelial cells, and they are involved in epithelial wound healing, melanocyte proliferation and migration, and hair cycling [18-20]. The SCF/c-kit system is also involved in the regenerative processes in the liver [21].
However, there have been only three studies that have examined the SCF in ocular tissues: infiltrating fibroblasts in pterygia, choroidal melanocytes, and iris pigment epithelial cells [22-24]. However, the localization and function of the SCF/c-kit system in ocular surface tissues are still undetermined.
The SCF is located at the steel (Sl) locus on chromosome 12 in humans and on chromosome 10 in mice, and c-kit at the white spotting (W) locus of chromosome 4 in humans and on mouse chromosome 5 [25-29]. A complete loss of SCF or c-kit function is lethal, but mice with mutations at either of these alleles (Sl/Sld and W/Wv) show similar defects in hematopoiesis, gametogenesis, and melanogenesis [30-32]. Mice with mutations at either locus typically have unpigmented coats, are sterile, and are deficient in erythrocytes and mast cells, as well as the precursors for multiple hematopoietic lineages. Thus, these mice have been used to investigate the SCF/c-kit system [12,30,31,33,34].
The purpose of this study was to determine the localization of SCF and c-kit in the mouse cornea, and to examine what role they play in corneal epithelial wound healing. To accomplish this, we first investigated corneal wound healing in both Sl/Sld- and W/Wv–mutant mice in vivo. We also examined cultured mouse corneal epithelial cells isolated from Sl/Sld and W/Wv mice.
We used WBB6F1-Sl/Sld and [29] WBB6F1-W/Wv [28] mice and WBB6F1+/+ mice for control. Genotypes of mutant mice were determined by SLC, Inc. (Hamamatsu, Japan). All of the mice were purchased from SLC, Inc. and housed in conformity with the Statement on the Use of Animals at Ehime University School of Medicine. Mice were gender-matched for the experiments and used at 6 to 10weeks of age. All mice were handled in accordance with the guidelines in the ARVO Statement for the Use of Animals in Ophthalmic and Vision Research.
Mice were anesthetized by an intraperitoneal injection of phenobarbital (50 mg/kg). There were 5 animals in each group, viz., the SCF mutant (Sl/Sld), c-kit mutant (W/Wv), and control WBB6F1-+/+ mice. A 2 mm central corneal epithelial defect was made on one eye with an excimer laser (EC-5000; NIDEK, Shizuoka, Japan), and the depth of wound was standardized at 30 µm. Corneas were stained with 0.4% methylene blue in phosphate-buffered saline (PBS), and the injured area was photographed at 6, 12, 18, 24, 30, 36, 42, and 48 h after creating the epithelial injury. The size of the injured area was measured on the images by Canvas™ ver 6.0 (Deneba software, Miami, FL).
In addition to assessing the degree of wound healing, animals (n=6 for each genotype and for each time point) were injected intraperitoneally with 8 mg/µl (200 µg/g bodyweight) of 5-bromo-2’-deoxyuridine (Sigma-Aldrich, St. Louis, MO) in PBS 2 h before euthanasia.
Total RNA was extracted from the corneas excised from WBB6F1+/+ mice using the RNeasy kit (Qiagen, Valencia, CA) and then reverse-transcribed using Omniscript Reverse Transcriptase (Qiagen) according to the manufacturer’s protocol. The extracts were divided into tubes containing PCR reaction mixture (AmpliTaq Gold; Applied Biosystems, Inc., Tokyo, Japan) with specific primers (Table 1).
The mixture was amplified with the TaKaRa PCR Thermal Cycler (TAKARA BIO Inc., Otsu, Japan): 40 cycles of 30 s at 94 °C, 30 s at 58 °C, and 1 min at 72 °C, followed by extension at 72 °C for 7 min. Then 5 µl of this solution was electrophoresced on 1.5% agarose gel and stained with 1 µg/ml of ethidium bromide and viewed with a transilluminator.
For immunostaining of SCF and c-kit, corneas were fixed in periodate-lysine-paraformaldehyde containing 4% sodium metaperiodate for 30 min and placed in 10% sucrose overnight. Samples were frozen and cut into 7 µm sections. For immunostaining for BrdU, eyes were fixed in 4% paraformaldehyde in PBS overnight and embedded in paraffin. Then 5 µm sections were cut, deparaffinized, and rehydrated. After the endogenous peroxidase was blocked with 0.3% hydrogen peroxidase for 20 min, sections were incubated with anti-mouse c-kit rabbit IgG (0.5 µg/ml; Santa Cruz, Santa Cruz, CA), anti-mouse SCF rabbit IgG (1.3 µg/ml, Genzyme, Cambridge, MA), or anti-BrdU monoclonal antibody (0.5 µg/ml, Lab Vision, Fremont, CA) for 24 h at 4 °C. The sections were developed with the peroxidase-DAB method using PAPKIT™ (ZYMED, San Francisco, CA) or M.O.M.™ immunodetection kits (Vector Laboratories, Burlingame, CA) according to the manufacturer’s instructions. Isotype-matched, irrelevant antibodies were used to rule out false positives for each immunostained group.
A 2 mm corneal epithelial defect was created on one eye of each mouse of the three groups as described above, and 8 ng/ml of recombinant mouse SCF (rmSCF, Genzyme) in 5 µl of PBS was applied every 6 h for up to 48 h. As control, an identical number of mice were given 5 µl of PBS-BSA (BSA) of the same protein concentration as the rmSCF. The injured corneas were photographed every 6 h and size of the injured area was measured as described above.
Corneas were removed at 6, 12, and 24 h after the epithelial injury from WBB6F1+/+ and W/Wv mice for scanning electron microscopy (SEM). The corneas were pre-fixed in 2.5% glutaraldehyde in 0.1 M cacodylate buffer (pH 7.4) for 2 h, then washed with cacodylate buffer, immersed in 1% tannic acid for 1 h, washed again with cacodylate buffer, and post-fixed with 2% osmium tetroxide in cacodylate buffer for 2 h. The corneas were then washed with distilled water, dehydrated in a graded ethanol series, and dried using the critical point drying method. The processed corneas were examined with SEM (Hitachi S-800; Hitachi, Tokyo, Japan).
Mouse corneal epithelial cells (MCECs) from WBB6F1+/+, -Sl/Sld, and -W/Wv mice were cultured as described [35]. The MCECs were in low-bovine pituitary extract medium CnT-50 (CELLnTEC, Bern, Switzerland), and the subconfluent cells at passage 3 (P3) were incubated in a growth factor starvation medium, CnT-20 (CELLnTEC), supplemented with 5 µg/ml of insulin (Invitrogen, Inc., Tokyo, Japan) for 24 h. After the growth factor starvation, MCECs were trypsinized into single cells for the BrdU incorporation assay and the cell attachment assay.
For the BrdU incorporation assay, the MCECs were resuspended in the starvation medium supplemented or not supplemented with 10 ng/ml of rmSCF (R&D Systems, Minneapolis, MN), seeded into 24 well tissue culture plates (Asahi Techno Glass, Funabashi, Japan) at a density of 2×104 cells/cm2, and incubated for 48 h at 37 °C under 95% humidity and 5% CO2. After incubation, the DNA synthetic activity of MCECs was measured with the BrdU Labeling and Detection Kit II (Roche Diagnostics, Tokyo, Japan) according to the manufacturer’s instructions. In brief, the culture medium was changed to the same fresh medium containing BrdU labeling reagent (1:1000) and incubated for 60 min at 37 °C under 95% humidity and 5% CO2. The MCECs were fixed in 70% ethanol buffered with 50 mM glycine buffer (pH 2, −20 °C), and then washed and incubated with a monoclonal anti-BrdU. The labeled cells were made visible by fluorescein-conjugated anti-mouse immunoglobulin (Vector Laboratories, Burlingame, CA). The nuclei were counter-stained with hoechst, and the total number of cells and the number of BrdU-positive nuclei were counted under a fluorescence microscope (IX70: Olympus, Tokyo, Japan). The BrdU incorporation is presented as the number of positively stained nuclei relative to the total number of cells.
For the cell attachment assay, the MCECs were resuspended in the starvation medium supplemented or not supplemented with 1, 10, or 30 ng/ml of rmSCF, seeded on to 96 well tissue culture plates (Corning, Inc., Corning, NY) at a density of 5×104 cells/well, and incubated for 2 h at 37 °C under 95% humidity and 5% CO2. After incubation, the wells were washed twice with PBS(-), and the attached MCECs were trypsinized into single cells. The number of cells attached to the plates was counted using an improved Neubauer counting chamber. The number of attached cells is presented as the number of attached cells relative to the non-SCF control.
Immortalized human corneal epithelial cells (HCECs) were grown to 100% confluence in supplemented hormonal epithelial medium consisting of Dulbecco's modified eagle medium (DMEM) with low glucose/F-12 (Invitrogen, Carlsbad, CA), 15% fetal bovine serum (FBS), 10 ng/ml epidermal growth factor (Invitrogen), 5 µg/ml insulin (Invitrogen), 5 mM L-glutamine (Invitrogen), 0.5% dimethyl sulfoxide (Sigma, St Louis, MO), and gentamicin (Invitrogen) [36]. All cells were grown at 37 °C in a humidified environment with 5% CO2. The culture medium was changed every 2 to 3 days.
To examine the involvement of SCF, the HCECs were resuspended in the starvation medium supplemented with 0, 10, 50, 250, or 1,000 ng/ml of anti-human goat SCF antibody (Santa Cruz) or control goat IgG (Santa Cruz), seeded on to 96 well tissue culture plates (Corning, Inc., Corning, NY) at a density of 5×104 cells/well, and incubated for 2 h at 37 °C under 95% humidity and 5% CO2. After incubation, the wells were washed twice with PBS(-), and the attached HCECs were counted as described. To determine the involvement of intracellular signaling transduction by c-kit, the HCECs were resuspended in the starvation medium supplemented or not supplemented with 5, 10, 25, and 50 µg/ml of genistein (Invitrogen), a tyrosine kinase inhibitor. To examine the involvement of integrins in cell attachment, the HCECs were resuspended with or without 125, 250, 500, and 1,000 µg/ml of GRGDSP or GRGESP peptide (SIGMA-ALDRICH, Ishikari, Japan). To examine the involvement of the extracellular matrix, which has integrin binding RGD regions, the HCECs were resuspended with 1000 ng/ml of anti-human goat SCF antibodies or control goat IgG, and seeded on to tissue culture plates treated with fibronectin, laminin, or type IV collagen (Asahi Techno Glass, Funabashi, Japan). The number of attached cells is presented as the number of attached cells relative to the cells in the control.
Statistical analyses to determine the significance of the differences between the experimental groups were performed by students’ t tests. The statistical significance level was set at p<0.05.
To determine whether SCF and c-kit were present in the cornea, we performed RT–PCR and immunohistochemistry on corneas obtained from WBB6F1+/+ mice. Both SCF and c-kit mRNAs were detected in the corneal tissue (Figure 1A). Immunohistochemistry showed that SCF was strongly expressed uniformly in the epithelia cells (Figure 1B), and c-kit was also expressed corneal epithelia, especially in the basal cells (Figure 1C). The c-kit receptor was expressed in both the central and peripheral cornea.
We examined the speed of corneal epithelial wound healing in ligand- or receptor-deficient mutant mice. The rate of wound healing in the ligand-deficient (Sl/Sld) mice and the receptor-deficient (W/Wv) mice was significantly delayed compared to that of the control WBB6F1+/+ mice (Figure 2A). The delay was significant even at 12 h after the epithelial injury when the Sl/Sld was 49% and the W/Wv mice was 47% of that of the controls (both p<0.01). In control WBB6F1+/+ mice, the wounds were almost completely closed at 42 h, while wound closure was 22% in the Sl/Sld mice and 28.5% in the W/Wv mice.
To determine whether topical application of SCF will enhance corneal wound healing, we applied recombinant SCF topically to the injured cornea of WBB6F1+/+ and Sl/Sld mice. The healing speed was accelerated by topical SCF in both WBB6F1+/+ and Sl/Sld mice within 12 h after the application (Figure 2B,C). The healing speed was especially prominent from the initial application up to 12 h after the SCF eyedrops; the residual defect area was 49% (untreated 64%) for WBB6F1+/+ mice and 63% (untreated 83%) for Sl/Sld at 12 h after debridement.
To determine whether the SCF/c-kit pathway enhances corneal epithelial cell proliferation during wound healing, the incorporation of BrdU by epithelial cells was determined during wound healing in WBB6F1+/+ and W/Wv mice. The number of BrdU-positive cells was significantly increased 24 h after excimer laser injury in WBB6F1+/+ (57.5±3.4 cells/section, n=6) and in W/Wv (54.6±2.3 cells/section, n=6). The difference in the number of labeled cells was not significant between the two genotypes (Figure 3).
Scanning electron microscopy was used to examine the leading edges of the corneal epithelial cells during wound closure in WBB6F1+/+ and W/Wv mice (Figure 4). The difference between the WBB6F1+/+ and W/Wv mice was clearly seen in the images at 24 h after epithelial injury. There were loosened cells in the W/Wv mouse cornea at 24 h after wounding, while the leading edge of WBB6F1+/+ mice cornea appeared to be firmly attached to the basement membrane.
To confirm the effect of SCF on the proliferation of the mouse corneal epithelial cells (MCECs), the incorporation of BrdU in the cultured MCECs was measured with or without addition of rmSCF to the culture medium. As in the in vivo assay, exposure to rmSCF did not accelerate the DNA synthetic activities in the WBB6F1+/+, SCF mutant Sl/Sld, and c-kit mutant W/Wv mice (Figure 5). The BrdU-positive cells in the rmSCF-stimulated cultures from WBB6F1+/+, Sl/Sld, and W/Wv mice were 83%, 102%, and 87% of the non-stimulated controls, respectively. There was no significant difference in these values between the rmSCF-stimulated cells and the non-stimulated controls (p>0.05, Man-Whitney U-test; Figure 5).
Exposure to rmSCF significantly enhanced the attachment of MCECs from WBB6F1+/+ mice to the culture plates. With 1, 10, and 30 ng/ml of rmSCF, the percentages of attached cells were 128%, 139%, and 157%, respectively, of the non-stimulated control (Figure 6). rmSCF exposure also enhanced the attachment of cells from SCF mutant Sl/Sld mice, and the attached cells that were stimulated increased from 177% to 252% of the control (Figure 6). On the other hand, rmSCF had no influence on the attachment of c-kit mutant cells from W/Wv mice; the attached percentage ranged from 100% to 112% of the control, which was not significantly different from that of the non-stimulated control (Figure 6).
Anti-SCF antibodies significantly reduce the percentage of attached HCECs. The percentages of attached cells that were incubated with 10, 50, 250, or 1,000 ng/ml of anti-SCF antibodies were 76.9%, 69.9%, 61.5%, and 43.6%, respectively, of the control (Figure 7A). The tyrosine kinase inhibitor genistein reduced the percentage of attached HCECs. The numbers of attached cells that were incubated with 25 and 50 µg/ml of genistein were significantly reduced to 89.5% and 62.5%, respectively, of the control (Figure 7B). The RGD peptide also reduced the percentage of HCECs attached. The attached cells that were incubated with 500 and 1000 µg/ml of GRGDSP peptide were also significantly reduced to 61.5% and 45.0%, respectively, of the control (Figure 7C). We further examined the involvement of SCF in ECMs that have RGD regions. The anti-SCF antibodies significantly reduced the attachment of HCECs to the culture plates treated with fibronectin to 78.6%, laminin to 90.3%, and type IV collagen to 74.4% of the control, respectively (Figure 7D).
Our results showed that both SCF and c-kit were expressed in normal mouse corneal epithelial cells, and that corneal epithelial wound healing was impaired in both Sl/Sld and W/Wv mice. The impaired corneal epithelial wound healing process recovered after topical application of SCF to Sl/Sld mice, a SCF mutant. These in vivo results suggested that the SCF/c-kit system is involved in corneal epithelial wound healing.
To determine by what mechanism the SCF/c-kit system enhanced corneal epithelial wound healing, we first examined whether this system stimulated the proliferation of the epithelial cells. No significant difference was found in BrdU incorporation between the wild type and W/Wv mice. This indicated that the absence of the SCF/c-kit system does not affect the proliferation of corneal epithelial cells.
We then examined the morphological changes in mutant mice by SEM in vivo. The SEM results showed that the corneal epithelial cells at the leading edge of the wound in W/Wv mouse were not stretched and did not attach to the basement membrane compared to wild type mouse. These results suggested that the absence of the SCF/c-kit system may retard the attachment of the cells to the basement membrane.
Several growth factors and membrane receptors that are involved in cell migration and cell attachment have been identified. These growth factors have been shown to regulate the healing of the injured corneal epithelium [37-42]. Nishida et al. [43,44] reported that EGF stimulates corneal epithelial cell attachment to fibronectin. Later, insulin-like growth factor-1 was shown to promote corneal epithelial cell migration and extracellular matrices production [45,46]. More recently, it was demonstrated that HB-EGF was more closely involved in promoting cell migration by cell attachments than by cell proliferation [41].
The results of our in vivo experiments suggested that the SCF/c-kit system is most likely involved in cell migration and cell attachment during corneal epithelial wound healing. The most effective method of determining the exact mechanism would be to compare the growth factors in isolated cells from wild type and SCF- and c-kit-deficient mice. Thus, we isolated the corneal epithelial cells from WBB6F1+/+, Sl/Sld and W/Wv mice by our technique [35] and examined the incorporation of BrdU and cell attachment.
As expected, enhanced cell attachment was observed in MCECs from wild type and Sl/Sld but not in W/Wv mice. In addition, no significant difference was detected between cells from wild type and from Sl/Sld or W/Wv mice in BrdU incorporation in in vitro experiments.
Thus, the results of the in vivo and in vitro experiments indicated that the SCF/c-kit system is probably involved in the attachment of corneal epithelial cells and not cell proliferation during wound healing. Although the function of the SCF/c-kit system in corneal epithelia has not been determined, it has been well shown that the SCF/c-kit system plays an important role in mast cell and progenitor cell attachment to the extracellular matrix [47-52]. In the epidermis, it has been recognized that SCF/c-kit system regulates melanocyte migration, differentiation, and proliferation [53,54]. In the cornea, it has been well documented that there is an interaction of cell adhesion molecules and ECMs controlled by other growth factors during epithelial wound healing [41,45,55-58]. It has also been demonstrated that the α6β1 integrin expression was upregulated by HB-EGF during corneal epithelial wound healing [41]. Thus, to investigate which cell adhesion molecules are regulated by SCF during corneal epithelial wound healing, we examined 88 cell adhesion-related molecules by real-time PCR using Primer Array® in an in vivo wound healing model. Unfortunately, the expression of none of the molecules examined was found to be changed significantly. Recently, Trusolino et al. [59] proposed that growth factors could change the functional state of integrins from inactive to acquired ligand-binding ability with no changes of the integrin expression. They further demonstrated that hepatocyte growth factor/scatter factor (HGF/SF) induced aggregation and triggering of efficient ligand-binding capability of integrin αvβ3 without changing the expression in human thyroid cells [59]. Shimizu et al. [60] also demonstrated that the SCF/c-kit system regulates the adhesion of intestinal epithelial cells to basement membrane matrix by fibronectin receptor, VLA-5, and fibronectin interactions. They also suggested that the adhesion was caused by a change in the avidity or quality of VLA-5 rather than an increase in the density of VLA-5. The authors mentioned that the changes in the growth factor-induced avidity or affinity of integrins were regulated by ligand-receptor signaling pathways. Thus, Simizu et al. [60] demonstrated that genistein, a tyrosine kinase inhibitor, significantly inhibited the adhesion of intestinal epithelial cells to fibronectin through VLA-5. Therefore, we further examined whether the SCF/c-kit cell signaling pathway was involved in the attachment of human corneal epithelial cells, using HCECs for a cell attachment assay. As expected, anti-SCF Ab and genistein significantly inhibited the attachment of HCECs, indicating that cell adhesion was induced by the c-kit signaling pathways following SCF/c-kit interaction. The reduction induced by RGP peptide indicated the involvement of integrin-ECM interactions on the adhesion of HCECs. Additional experiments demonstrated that SCF/c-kit system might enhance the avidity or affinity of integrins to adhere to fibronectin, laminin, and type IV collagen. Although we could not determine the particular type of integrin pairs involved in the cell attachment, our results suggest that the SCF/c-kit system may be involved in the cell attachment during corneal wound healing by the induction of the avidity or affinity by one or several members of the integrin families. To determine the precise mechanisms, further investigations will be needed.
In conclusion, our results showed that SCF and c-kit were expressed in normal mouse cornea, and they provided evidence that the SCF/c-kit system plays a role in corneal wound healing by altering epithelial cell attachment.