Effect of L-ascorbic acid 2-phosphate on cultured rabbit keratocytes (the second report)

We examined the effect of L-ascorbic acid 2-phosphate (P-Asc) on the proliferation of cultured rabbit keratocytes. P-Asc is a derivative of L-ascorbic acid and it yields more prolonged effects of vitamin C in solution than L-ascorbic acid. The proliferation of cultured rabbit keratocytes was promoted by the presence of P-Asc in culture medium for 10, 20, and 30 days. Transmission electron microscopic observations revealed that the cells were more multilayered in the presence of P-Asc (0.1mM) for thirty days than those in the absence of P-Asc. Moreover, this effect of P-Asc was attenuated by azetidine 2-carboxylic acid which is an inhibitor of collagen synthesis. Hence, it is suggested that the promotive effect of P-Asc on the growth of cultured keratocytes is related to the synthesis of collagen. Based on our observations, P-Asc may have a therapeutic effect on corneal stromal damages such as a corneal chemical burn and surgical trauma.     

L-ascorbic acid 2-phosphate enhances the production of type I and type III collagen peptides in cultured rabbit keratocytes.

We studied the effect of L-ascorbic acid 2-phosphate (P-Asc), a long-acting phosphate derivative of L-ascorbic acid, on the production and secretion of type I and type III collagen peptides in cultured rabbit keratocytes using immunohistochemistry and enzyme immunoassay. P-Asc enhanced production and secretion of these collagen peptides. Our observations support a therapeutic role for P-Asc in the repair of corneal stromal damage such as caused by corneal chemical burn.     

Ultrastructural effect of L-ascorbic acid 2-phosphate on cultured keratocytes.

I studied the effect of L-ascorbic acid 2-phosphate (P-Asc), a long-acting derivative of L-ascorbic acid, on the fine structures of cultured rabbit keratocytes. The results showed that cells cultured with 0.1 mM P-Asc for 30 days were more markedly multilayered than those grown without P-Asc. Dilation of the cisternae of the endoplasmic reticulum in the control cells indicated an accumulation of protein (probably procollagen). In addition, many lysosome-like structures, which may degrade underhydroxylated procollagen, were observed in the cytoplasm of the control cells. A slight increment of free ribosomes was also found within the control cells. P-Asc enhanced the multilayerization of cultured keratocytes. We conclude that the changes seen in the cytoplasm are due to the effect of P-Asc acting as vitamin C.     

l-Ascorbic acid 2-phosphate,a phosphate derivative of l-ascorbic acid,enhances the growth of cultured rabbit keratocytes

We examined the effect of l-ascorbic acid 2-phosphate (P-Asc) on the proliferation of cultured rabbit keratocytes. P-Asc is a phosphate derivative of l-ascorbic acid and has more prolonged vitamin C activity in solution than does l-ascorbic acid. The proliferation of cultured keratocytes was promoted by the presence of P-Asc in culture medium. Transmission electron microscopic observations revealed that cells were more multilayered after culture in the presence of P-Asc (0.1 mM) for 30 days than were those cultured in the absence of P-Asc. The effect of P-Asc was abrogated by l-azetidine 2-carboxylic acid, which is an analogue of proline that inhibits the production and secretion of collagen. Our observations support a therapeutic role for P-Asc in the repair of corneal stromal damage such as that caused by a corneal chemical burn. Offprint requests to: S. Saika     

Ascorbic acid phosphate ester and wound healing in rabbit corneal alkali burns: Epithelial basement membrane and stroma

We examined the effect of L-ascorbic acid 2-phosphate (P-Asc) on the healing of alkali-burned corneas in rabbits. Round filter paper containing 1 N NaOH was applied to the central cornea for 60 or 120 s to produce the alkali burn. Animals were treated with topical saline, 10% ascorbate, or 6.5% P-Asc applied on the cornea. The corneas were then examined histologically. Burned stroma showed no toluidine blue staining, indicating a loss of glycosaminoglycan. In the 60-s burn group, P-Asc reduced the size of the unstained area as compared with the control. Transmission electron microscopy showed basal lamina under new epithelia in the corneas treated with ascorbate or P-Asc, but not in controls. These observations support the theory that P-Asc may have a therapeutic role in the repair of corneal alkali burns.     

Stimulatory effect of pseudomonal elastase on collagen degradation by cultured keratocytes

PURPOSE. The pathobiology of corneal ulceration induced by Pseudomonas aeruginosa was investigated by characterization of the pseudomonal pathogenic factors responsible for degradation of the collagen matrix. METHODS. Three-dimensional gels of type I collagen containing (or not) rabbit keratocytes were incubated in the presence of either culture supernatant of P. aeruginosa strain PAO1 or pseudomonal pathogenic factors (elastase, lipopolysaccharide, or exotoxin A), and the extent of collagen degradation was assessed after 24 hours by measurement of released hydroxyproline. Activation of matrix metalloproteinases (MMPs) produced by keratocytes was also examined by gelatin zymography and immunoblot analysis. RESULTS. In the absence of keratocytes, the PAO1-conditioned medium increased the extent of collagen degradation. The conditioned medium also promoted keratocyte-mediated collagen degradation. Of the pseudomonal pathogenic factors examined, only elastase degraded collagen directly as well as stimulated keratocyte-mediated collagen degradation. Culture supernatant of elastase-deficient P. aeruginosa (lasR or lasB) mutants had no effect on collagen degradation in the absence or presence of keratocytes. Elastase also induced the conversion of the inactive precursors of MMP-1, -2, -3, and -9 produced by keratocytes to the active forms of the enzymes. CONCLUSIONS. These results suggest that pseudomonal elastase both degrades type I collagen directly and promotes collagen degradation mediated by keratocytes, the latter effect being likely attributable, at least in part, to the activation of proMMPS:     

绿脓杆菌对角膜基质细胞介导的胶原降解作用的实验研究

目的 探讨绿脓杆菌性角膜炎组织破坏机制,为临床治疗提供理论依据。方法 Ⅰ型胶原凝胶,混悬及不混悬角膜基质细胞,与绿脓杆菌培养液共同培养２４ｈ,超滤去除天然胶原纤维,超滤液经过水解,分光光度计测定其羟脯氨酸含量。同时检测基质金属蛋白酶抑制剂Ｇａｌａｒｏｄｉｎ对胶原降解作用的影响。结果 绿脓杆菌培养液可直接降解Ⅰ型胶原,如同时存在角膜基质细胞此作用增强。无论 角膜基质细胞存在与否,Ｇａｌａｒｄｉｎ可明     

Differential regulation of collagen degradation by rabbit keratocytes and polymorphonuclear leukocytes

PURPOSE: Both activated keratocytes and infiltrated polymorphonuclear leukocytes (PMNs) contribute to corneal ulceration by degrading stromal collagen. The regulation of such collagen degradation by inflammatory cytokines was investigated with rabbit keratocytes and PMNs cultured in three-dimensional collagen gels. METHODS: Rabbit keratocytes or PMNs were cultured for 24 h in three-dimensional gels of type I collagen in the presence of plasminogen and various concentrations of either interleukin (IL)-1alpha, IL-6, IL-8, or tumor necrosis factor-alpha (TNF-alpha). Degradation of collagen during culture was assessed by measurement of released hydroxyproline. RESULTS: IL-1alpha increased the amount of collagen degraded by keratocytes or PMNs in a dose-dependent manner, whereas IL-6 had no effect on collagen degradation by either cell type. IL-8 increased the extent of collagen degradation by PMNs but not that by keratocytes, and TNF-alpha promoted collagen degradation by keratocytes but not that by PMNs. CONCLUSION: Inflammatory cytokines regulate collagen degradation by rabbit keratocytes and PMNs in culture in a differential manner, and therefore may contribute to the roles of these cells in corneal ulceration.     

IGF-II and collagen expression by keratocytes during postnatal development

Keratocytes produce the extensive stromal matrix of the cornea during the late embryonic and neonatal time periods. We propose to test the hypothesis that their biosynthetic activity declines during this process. Keratocytes were isolated from corneas of 6-8-week-old rabbits and corneas of 1-2-year-old cows and their ability to proliferate and synthesize collagen in serum-free media was determined. Rabbit keratocyte cultures increased 38% in DNA content after one week and deposited collagen type I and IGF-II in the media. Bovine keratocyte cultures, in contrast, did not increase in DNA or produce detectable collagen and IGF-II. Bovine keratocytes cultured in media previously conditioned by rabbit keratocytes, however, increased 56% in DNA content, and deposited collagen type I into the media. Microarray analysis of mRNA from neonatal and adult mouse keratocytes was used to confirm these differences. Compared to adult mouse keratocytes, neonatal keratocytes showed high expression levels of IGF-I, IGF-II and collagen types III and V. Since previous studies showed that IGFs stimulate bovine keratocytes to proliferate and to synthesize procollagen type I, we therefore propose that the results of this study suggests that the IGFs may play an important role in regulating early corneal growth in vivo.     

Collagenolytic Activity of Keratocytes Cultured in a Collagen Matrix

To study the mechanism of collagen degradation by keratocytes, we developed the new in vitro model in which keratocytes were cultured three-dimensionally in a collagen matrix. Subcultured rabbit keratocytes were embedded in a type I collagen matrix and cultured in serum-free medium. Collagenolytic activity of the cells was determined by measuring the amount of hydroxyproline released into the medium from degraded collagen. Activities of collagenase in the medium were also measured, using collagen labeled with fluorescein isothiocyanate as a substrate. The presence of plasminogen was required for collagen degradation by keratocytes. In the presence of plasminogen, the amount of collagen degradation depended on both the cultivation period and the number of cells. The addition of interleukin-1 (IL-1) stimulated the collagen degradation in a dose-dependent manner. This stimulatory effect of IL-1 was completely inhibited by the addition of IL-1 receptor antagonist (IL-1ra). Collagenase activity in the medium was stimulated by the addition of IL-1, and IL-1ra antagonized this stimulatory effect. These findings indicate that our present model may be useful for investigating the mechanism of collagen degradation by keratocytes.     

Rabbit corneal endothelial cells modulated by polymorphonuclear leukocytes are fibroblasts. Comparison with keratocytes

The authors previously reported that polymorphonuclear leukocytes modulate rabbit corneal endothelial cells into fibroblasts, which acquire the characteristics of fibroblasts. The progeny of the fibroblastic corneal endothelial cells (FCEC) were further studied to compare the characteristics of the fibroblast with those of keratocytes as a function of culture age. During 11 days in culture, FCEC showed 32 population doublings, whereas keratocytes underwent 10 population doublings. When collagen phenotypes of both cultures were analyzed as a function of culture age, labeled collagens in both cultures were fractionated into types I, III, and V. The proportion of each collagen was relatively unchanged in keratocytes regardless of culture age: type I accounted for 92-96%, type III for 2-6% and type V for 2-5%. In contrast, the profiles were significantly changed in FCEC: at day 2, type I accounted for 57%, type III for 37.5%, and type V 5.5%. Over the following 2 days, type I increased to approximately 75%, whereas type III collagen decreased to approximately 20%. As FCEC multilayered, type I collagen synthesis reached a stationary level of 80%, with 12% of type III. When the stoichiometry of type I collagen was compared, the alpha 1/alpha 2 ratio was 6.2 in FCEC and the ratio was 3.5 in keratocytes at day 2. The ratio reached a normal value at day 7 in FCEC and at day 3 in keratocytes. The synthesis of type I trimer and transient alteration of type I/III and the rapid growth rate at early stages of growth, indicate that FCEC behave like cells seen in wound healing or other rapidly growing tissues, in contrast to the stabilized keratocytes.     

Effect of growth factors on collagen lattice contraction by human keratocytes.

A three-dimensional gel contraction model was used to evaluate interactions between human keratocytes and different kinds of collagen in the presence or absence of various growth factors. Bovine collagen type I or human placental copolymerized collagen type I/III was used to create the lattices. Normal keratocytes from neonatal, aged, and insulin-dependent diabetic donors, as well as abnormal keratocytes from a donor with macular corneal dystrophy, were cultured. Growth factors included epidermal growth factor (EGF), basic fibroblastic growth factor (FGF), insulin-like growth factor (IGF-I), and platelet-derived growth factor homodimer beta beta (PDGF). Gel area and optical transmittance were determined from computerized measurements. Dose-response experiments (0.01-100 ng/ml) demonstrated that PDGF at 10 ng/ml (P less than 0.005) and EGF at 1 and 10 ng/ml (P less than 0.0001) were the most effective in promoting gel contraction, compared to IGF-I and FGF. Comparison of cell strains revealed different dose-response profiles. Cells from insulin-dependent diabetics and cells from a donor with macular dystrophy contracted lattices more rapidly than cells from normal neonates (P less than 0.0001). Lattices of copolymerized human collagen type III/I demonstrated significantly reduced contraction rates (P less than 0.0001) and increased optical transmittance, compared to bovine collagen type I lattices. Ultrastructural studies revealed that keratocytes extend processes to form a network within the collagen lattice. Specialized intercellular junctional complexes were observed by transmission electron microscopy. This model provides a useful in vitro corneal stroma-equivalent for the study of keratocyte, extracellular matrix, and growth factor interactions.     

Effects of riboflavin/UVA corneal cross‐linking on keratocytes and collagen fibres in human cornea

Purpose: To evaluate the effects of corneal cross‐linking on keratocytes and collagen fibres in human corneas. Methods: Fifteen corneal buttons were examined. Ten were from patients with keratoconus submitted to penetrating keratoplasty and five of them were treated with cross‐linking 6 months before penetrating keratoplasty. Five normal corneal buttons from healthy donors were used as controls. All samples were prepared for TUNEL assay and Western blot analysis for the detection of keratocyte apoptosis and immunohistochemical analysis for the morphological evaluation of keratocytes and collagen fibre diameter. Results: Normal corneas exhibited no TUNEL‐positive keratocytes and keratoconic and cross‐linked corneas showed moderate apoptotic cells mainly in the anterior part of the stroma. This apoptotic trend was confirmed by the cleavage of poly (ADP‐ribose) polymerase assessed using Western blot. The Ki‐67 staining showed a significant increase in the keratocyte proliferation in cross‐linked corneas compared with normal and keratoconus. In cross‐linked corneas CD34‐positive keratocytes were regularly distributed throughout the whole corneal stroma as in the control, and keratoconus was associated with patchy loss of immunoreactivity. The immunohistochemical analysis of collagen type I showed a significant increase in fibre diameter of cross‐linked corneas compared with control and keratoconus. Conclusion: Corneal cross‐linking leads to keratocyte damage; after 6 months a repopulation by proliferating cells, a distribution of CD34‐positive keratocytes as in control and an increase in collagen fibre diameter were observed. These modifications are the morphological correlate of the process leading to an increase in biomechanical stability.     

Changes in extracellular matrix components after excimer laser photoablation in rat cornea

PURPOSE: To learn more about corneal wound healing after excimer laser photoablation. METHODS: Observations were made on the chronological changes in type I collagen, fibronectin, laminin, and type IV collagen after excimer ablation of rat cornea. Immunohistochemical techniques were used. RESULTS: There was no obvious change in the localization of type I collagen in the ablated area, but the localization of fibronectin, laminin, and type IV collagen changed remarkably. One day after ablation, immunofluorescent staining for fibronectin increased on the ablated surface. Subsequently, the fluorescence of fibronectin, laminin, and type IV collagen increased remarkably; in particular, the localization of these extracellular matrix proteins was sustained in the shallow layer of the stroma until about 24 weeks after ablation. Hematoxylin-eosin staining indicated that keratocytes temporarily disappeared 1 day after ablation, and activated keratocytes then migrated to the ablated areas. CONCLUSIONS: These results suggest that activated keratocytes might be synthesizing the extracellular matrix components. Therefore sustained responses of keratocytes may be induced by excimer laser photoablation.     

Localization of collagen (I) and collagenase mRNA by in situ hybridization during corneal wound healing after epikeratophakia or alkali-burn.

The expression and localization of type I collagen and collagenase gene were studied by in situ hybridization using rabbit cornea during wound healing following epikeratophakia or alkali-burn. In corneas 24 days after epikeratophakia, alpha 1(I) collagen mRNA was detected in keratocytes which had migrated from the host cornea into the keratolens. In contrast, collagenase mRNA was detected in cells which seemed to be inflammatory cells around the suture between the host stroma and the keratolens. The increase of alpha 1(I) collagen mRNA in keratocytes was observed in corneas 94 days after epikeratophakia and in alkali-burned corneas 1-2 months after the burn. These results provide evidence that keratocytes synthesize collagen and that this synthesizing activity lasts for a long period during corneal wound healing.     

Effects of tranilast on cultured rabbit corneal keratocytes and corneal haze after photorefractive keratectomy

PURPOSE: In vitro and in vivo studies were performed to elucidate the effects of tranilast on cellular proliferation and collagen synthesis. METHODS: Subculturing was carried out using keratocytes from rabbits that underwent photorefractive keratectomy (PRK) and developed corneal haze, and keratocytes from normal rabbit cornea. RESULTS: Tranilast suppressed proliferation in cultured keratocytes from the corneal haze region at doses of 30 and 300 micromol/L and collagen synthesis at doses of 3, 30, and 300 micromol/L. Normal corneal cultures showed suppression of keratocyte proliferation and collagen synthesis only at a high dose of tranilast (300 micromol/L). Betamethasone suppressed proliferation of keratocytes in both haze and normal cornea at a dose of 10 micromol/L, as well as collagen synthesis at respective doses of 1 and 10 micromol/L. Diclofenac sodium suppressed collagen synthesis of keratocytes in haze cornea at a high dose of 100 micromol/L, and in keratocytes in normal cornea, at doses of 10 and 100 micromol/L. In an in vivo study, either 0.5% tranilast, 0.1% betamethasone phosphate eye drops, or a tranilast base solution (control) was instilled four times daily to rabbits that had undergone PRK. Weekly evaluation of the inhibitory effect of these drugs on the development of haze was performed 2 weeks after surgery. Tranilast suppressed haze 6-13 weeks after PRK, but betamethasone phosphate showed no effect. CONCLUSION: These results indicate that tranilast is potentially effective for inhibiting the corneal haze that occurs after PRK.     

Effect of galardin on collagen degradation by Pseudomonas aeruginosa

The authors examined the effect of a synthetic peptidyl hydroxamate inhibitor of matrix metalloproteinase, Galardin, on collagen degradation by Pseudomonas aeruginosa (P. aeruginosa) in the presence or absence of keratocytes. Type I collagen gels, with or without suspended keratocytes, were incubated under medium containing sterile P. aeruginosa culture broth and/or Galardin for 24 hr. Degradation of collagen fibrils during culture was measured by the release of hydroxyproline. The conditioned media were also subjected to gelatin zymography and Western blotting to analyse the activation, by P. aeruginosa factor(s), of matrix metalloproteinases (MMPs) released by keratocytes. The effects of protease inhibitors, aprotinin, leupeptin and pepstatin, on collagen degradation by P. aeruginosa were also examined. P. aeruginosa broth by itself induced collegen gel degradation. When keratocytes were present, P. aeruginosa broth increased the amount of degraded collagen even further. Galardin significantly reduced the amounts of collagen degraded by P. aeruginosa culture broth, whether keratocytes were present or absent in the gel. However, the protease inhibitors had no inhibitory effects on collagen degradation. Gelatin zymography and Western blotting revealed that inactive proMMP-1, -2 and -3, released by keratocytes, were converted to active forms in the presence of P. aeruginosa broth. Galardin decreased the amounts of active MMPs and increased those of inactive proMMPs, suggesting that Galardin inhibited the activation of proMMPs by P. aeruginosa. The present results suggest that Galardin inhibits the keratocyte-mediated collagen degradation by P. aeruginosa culture broth, resulting from preventing the conversion of proMMPs to active MMPs.     

Promotion of minTBP-1-PRGDN on the attachment, proliferation and collagen I synthesis of human keratocyte on titanium

AIM:To investigate the influence of minTBP-1-PRGDN on the attachment, proliferation and collagen I synthesis of human keratocyte on titanium (Ti) surface.METHODS:The chimeric peptide RKLPDAPRGDN (minTBP-1-PRGDN) was synthesized by connecting RKLPDA (minTBP-1) to the N-terminal of PRGDN , the influence of minTBP-1-PRGDN on the attachment, proliferation and collagen I synthesis of human keratocyte on Ti surface were tested using PRGDN and minTBP-1as controls. The keratocytes attached to the surface of Ti were either stained with FITC-labeled phalloidin and viewed with fluorescence microscope or quantified with alamar Blue method. The proliferation of keratocytes on Ti were quantified with 3-(4,5-dim- ethylthiazol-2-yl)-2, 5-diphenyltetrazolium bromide up-taking methods. The secretion of type I collagen were determined using an ELISA kit.RESULTS:The results showed that minTBP-1-PRGDN at a concentration of 100ng/mL was the most potent peptide to enhance the attachment of human keratocytes to the surface of Ti (1.40±0.03 folds, P=0.003), to promote the proliferation (1.26±0.05 folds, P=0.014) and the synthesis of type I collagen (1.530±0.128, P=0.008). MinTBP-1 at the same concentration could only promote the attachment (1.13±0.04 folds, P=0.020) and proliferation(1.15±0.06 folds, P=0.021), while PRGDN had no significant influence (P＞0.05).CONCLUSION:Our data shows that the novel chimeric peptide minTBP-1-PRGDN could promote the attachment, proliferation and type I collagen synthesis of human keratocytes on the surface of Ti.     

Reconstructed corneas: effect of three-dimensional culture, epithelium, and tetracycline hydrochloride on newly synthesized extracellular matrix

PURPOSE: To evaluate the influence of the 3-dimensional collagen-glycosaminogycan-chitosan (CGC 3D) scaffold, epithelialization, and the addition of tetracycline hydrochloride on the ultrastructural organization, measured by the diameter and spacing of newly synthesized collagen I fibrils. METHODS: Little is known about the role of interactions between epithelial cells and fibroblasts in controlling the extracellular matrix of the cornea. We developed a hemicornea from a CGC 3D matrix cocultured with keratocytes and human epithelial cells. The keratocytes colonized this substrate, proliferated, and synthesized the extracellular matrix, reproducing a living stroma equivalent. RESULTS: Without a 3D scaffold, the collagen fibrils produced had an average diameter that was 42.7 nm and sigma = 16.9 nm. In the CGC 3D scaffold, the fibrils had an average diameter of 33.4 nm, with little dispersion (sigma = 6.7 nm), suggesting a greater regulation. The epithelium permitted a significant reduction in fibril diameter and interfibrillar spacing. Tetracycline hydrochloride had no effect on spacing but did have a significant effect on fibril diameter. We found positive interactions between the epithelium and tetracycline hydrochloride on the regulation of collagen fibrils but not on spacing. The presence of epithelium led to the increased formation of collagens I and V in the subepithelial area of the newly formed matrix. Type VI collagen was localized around the keratocytes throughout the matrix. CONCLUSIONS: Epithelialization and the 3D scaffold had a great influence on the diameter of collagen I fibrils.     

Characterization of corneal keratocyte morphology and mechanical activity within 3-D collagen matrices

The purpose of this study was to assess quantitatively the differences in morphology, cytoskeletal organization and mechanical behavior between quiescent corneal keratocytes and activated fibroblasts in a 3-D culture model. Primary cultures of rabbit corneal keratocytes and fibroblasts were plated inside type I collagen matrices in serum-free media or 10% FBS, and allowed to spread for 1-5 days. Following F-actin labeling using phalloidin, and immunolabeling of tubulin, α-smooth muscle actin or connexin 43, fluorescent and reflected light (for collagen fibrils) 3-D optical section images were acquired using laser confocal microscopy. In other experiments, dynamic imaging was performed using differential interference contrast microscopy, and finite element modeling was used to map ECM deformations. Corneal keratocytes developed a stellate morphology with numerous cell processes that ran a tortuous path between and along collagen fibrils without any apparent impact on their alignment. Fibroblasts on the other hand, had a more bipolar morphology with pseudopodial processes (P ≤ 0.001). Time-lapse imaging of keratocytes revealed occasional extension and retraction of dendritic processes with only transient displacements of collagen fibrils, whereas fibroblasts exerted stronger myosin II-dependent contractile forces (P < 0.01), causing increased compaction and alignment of collagen at the ends of the pseudopodia (P < 0.001). At high cell density, both keratocytes and fibroblasts appeared to form a 3-D network connected via gap junctions. Overall, this experimental model provides a unique platform for quantitative investigation of the morphological, cytoskeletal and contractile behavior of corneal keratocytes (i.e. their mechanical phenotype) in a 3-D microenvironment.