Diet-dependent function of the extracellular matrix proteoglycan Lumican in obesity and glucose homeostasis.

OBJECTIVE: Extracellular matrix remodeling is required for adipose expansion under increased caloric intake. In turn, inhibited expandability due to aberrant collagen deposition promotes insulin resistance and progression towards the metabolic syndrome. An emerging role for the small leucine-rich proteoglycan Lumican in metabolically driven nonalcoholic fatty liver disease sparks an interest in further understanding its role in diet-induced obesity and metabolic complications. METHODS: Whole body ablation of Lumican (Lum-/-) gene and adeno-associated virus-mediated over-expression were used in combination with control or high fat diet to assess energy balance, glucose homeostasis as well as adipose tissue health and remodeling. RESULTS: Lumican was found to be particularly enriched in the stromal cells isolated from murine gonadal white adipose tissue. Likewise murine and human visceral fat showed a robust increase in Lumican as compared to fat from the subcutaneous depot. Lumican null female mice exhibited moderately increased fat mass, decreased insulin sensitivity and increased liver triglycerides in a diet-dependent manner. These changes coincided with inflammation in adipose tissue and no overt effects in adipose expandability, i.e. adipocyte formation and hypertrophy. Lumican over-expression in visceral fat and liver resulted in improved insulin sensitivity and glucose clearance. CONCLUSIONS: These data indicate that Lumican may represent a functional link between the extracellular matrix, glucose homeostasis, and features of the metabolic syndrome.

Impaired skin wound healing in lumican-null mice.

BACKGROUND: Previous studies have demonstrated that the lack of lumican delayed corneal wound healing in lumican-null (Lum(-/-) ) mice. This defect is rescued by the addition of glycosylated lumican core protein to the injured corneas. OBJECTIVES: We examined the hypothesis that lumican is also required for the healing of cutaneous wounds using Lum(-/-) mice. METHODS: We demonstrated the basic thinner skin phenotypes in Lum(-/-) mice at different time points and the changes in arrangement of collagen fibres by transmission electron microscopy (TEM). A full skin thickness wound was generated by punch biopsy (6 mm diameter) in experimental Lum(-/-) and wild-type mice. The closure of injured skin was measured after various periods of time (3, 6, 12, 18 days). Specimens of injured and uninjured skin (serving as control) were then subjected to morphological examination with haematoxylin and eosin and Masson trichrome stains, and by TEM. Immunohistochemical staining with anti-CD68 antibody was used to assess the presence of macrophages in injured skin healing for various periods of time. Semiquantitative reverse transcription-polymerase chain reaction (RT-PCR) was used to elucidate the transforming growth factor (TGF)-ß1-induced myofibroblast phenotypic genes. RESULTS: Skin of adult Lum(-/-) mice (3 months and older) was much thinner (40% less) than that of age-matched wild-type mice. This phenomenon was aggravated in older mice. TEM revealed disoriented and irregular collagen fibrils in the dermis of Lum(-/-) mice. Delayed wound healing with an increase in inflammatory macrophages was compatible with the delayed response of the expression of TGF-ß1, type I collagen α1 and fibronectin at the mRNA level by semiquantitative RT-PCR in the Lum(-/-) mice. CONCLUSIONS: Our data demonstrate that lumican plays pivotal roles in skin collagen fibrillogenesis and wound healing.

Tubedown-1 in remodeling of the developing vitreal vasculature in vivo and regulation of capillary outgrowth in vitro.

Tubedown-1 (tbdn-1) is a mammalian homologue of the N-terminal acetyltransferase subunit NAT1 of Saccharomyces cerevisiae and copurifies with an acetyltransferase activity. Tbdn-1 expression in endothelial cells becomes downregulated during the formation of capillary-like structures in vitro and is regulated in vivo in a manner which suggests a functional role in dampening blood vessel development. Here we show that tbdn-1 is expressed highly in the vitreal vascular network (tunica vasculosa lentis and vasa hyaloidea propria) during the pruning and remodeling phases of this transient structure. The vitreal blood vessels of mice harboring a targeted inactivation of TGF-beta2 fail to remodel and abnormally accumulate, a phenomenon reminiscent of the ocular pathology resembling persistent fetal vasculature (PFV) in humans. Since suppression of normal tbdn-1 expression has been previously observed in retinal vessel proliferation, we analyzed vitreal vascular changes and tbdn-1 expression in TGF-beta2(-/-) eyes. The nuclei of vitreal vessel endothelial cells in TGF-beta2(-/-) eyes express proliferating cell nuclear antigen (PCNA) and exhibit increased levels of active (P42/44)mitogen-activated protein kinase (phospho-(P42/44)MAPK), characteristics consistent with proliferative endothelial cells. In contrast to normal vitreal vessels, collagen IV expression exhibited a disorganized pattern in the TGF-beta2(-/-) vitreal vessels, suggesting vessel disorganization and possibly a breakdown of vessel basal laminae. Moreover, vitreal vessels of TGF-beta2(-/-) mice lack expression of pericyte markers (CD13, alpha smooth muscle actin) and show ultrastructural changes consistent with pericyte degeneration. The accumulating vitreal blood vessels of TGF-beta2(-/-) mice, while maintaining expression of the endothelial marker von Willebrand Factor, show a significant decrease in the expression of tbdn-1. We addressed the functional role of tbdn-1 in the regulation of vitreal blood vessels using an in vitro model of choroid-retina capillary outgrowth. Clones of the RF/6A fetal choroid-retina endothelial cell line showing suppression of tbdn-1 levels after overexpression of an antisense TBDN-1 cDNA display a significant increase in the formation of capillary-like structures in vitro compared with controls. These findings suggest that tbdn-1 inhibits capillary-like formation in vitro and may serve to dampen vitreal blood vessel formation preceding the regression of the vitreal vasculature during development. Our results also suggest that tbdn-1 may participate with TGF-beta2 in regulating normal development of the vitreal vasculature.

Corneal epithelial wound healing.

One of the important functions of the cornea is to maintain normal vision by refracting light onto the lens and retina. This property is dependent in part on the ability of the corneal epithelium to undergo continuous renewal. Epithelial renewal is essential because it enables this tissue to act as a barrier that protects the corneal interior from becoming infected by noxious environmental agents. Furthermore, the smooth optical properties of the corneal epithelial surface are sustained through this renewal process. The rate of renewal is dependent on a highly integrated balance between the processes of corneal epithelial proliferation, differentiation, and cell death. One experimental approach to characterize these three aspects of the renewal process has been to study the kinetics and dynamics of corneal re-epithelialization in a wound-healing model. This effort has employed in vivo and in vitro studies. From such studies it is evident that the appropriate integration and coordination of corneal epithelial proliferation, adhesion, migration, and cell demise is dependent on the actions of a myriad of cytokines. Our goal here is to provide an overview into how these mediators and environmental factors elicit control of cellular proliferation, adhesion, migration, and apoptosis. To this end we review the pertinent literature dealing with the receptor and the cell signaling events that are responsible for mediating cytokine control of corneal epithelial renewal. It is our hope that a better appreciation can be obtained about the complexity of the control processes that are responsible for assuring continuous corneal epithelial renewal in health and disease.

Immunohistochemical study of subepithelial haze after phototherapeutic keratectomy.

PURPOSE: Subepithelial haze is a frequent complication and is often the cause of regression after photorefractive keratectomy (PRK). The lack of understanding of this undesirable complication following PRK is in part due to the limited availability of suitable tissues for pathological studies. METHODS: We examined the expression of various extracellular components in the cornea of a 46-year-old man who underwent phototherapeutic keratectomy (PTK) to remove a central corneal scar secondary to trauma. The patient subsequently underwent penetrating keratoplasty. A scar-free region containing an area of slight subepithelial haze adjacent to normal cornea was used for immunohistochemical staining with antibodies directed against cytoskeletal proteins, ie, vimentin, desmin and smooth muscle actin, and the extracellular components, laminin, heparan sulfate, keratan sulfate, and collagen types III, IV, V, and VII. RESULTS: Immunohistochemistry revealed that basal epithelial cells expressed components of basement membrane. The stromal fibroblasts within the haze tissue were labeled by anti-smooth muscle actin antibodies, a characteristic of myofibroblasts, which synthesized and secreted extracellular matrix components that contributed to the formation of the disorganized collagenous matrix and may account for subepithelial haze. CONCLUSIONS: The expression patterns for the cytoskeletal proteins and extracellular components indicated that the formation of subepithelial haze is a process of tissue remodeling, involving both corneal basal epithelial cells and keratocytes during wound repair.

MK/T-1, an immortalized fibroblast cell line derived using cultures of mouse corneal stroma.

PURPOSE: Immortalized cell lines representing fibroblast cells from corneal stroma would facilitate studies of corneal cell biology and injury response. METHODS: Primary cultures of cells derived from mouse corneal stroma were transfected with a human telomerase reverse transcriptase (hTERT) expression construct to maximize chances of cellular immortalization. A resulting cell line was analyzed for telomerase activity, cell growth characteristics, senescence and gene expression patterns. Specific responses to transforming growth factor beta (TGF-beta) were also analyzed. RESULTS: An immortalized cell line was derived and was named MK/T-1. MK/T-1 cells show no signs of cellular senescence or transformation at over 100 passages. Telomerase activity was significantly higher in MK/T-1 cells as compared to the parental cell cultures. However, relative telomere length (RTL) in the MK/T-1 and parental cells was not significantly different. Senescence associated beta-galactosidase (SA-beta-Gal) activity was not detected in late passage MK/T-1 cells while the parental cells had already upregulated SA-beta-Gal at high levels by passage 9. The MK/T-1 cells express vimentin, tubulin, lumican, mimecan, decorin and collagen I, but not keratocan. Exposure of the MK/T-1 cells to TGF-beta induces the expression of smooth muscle alpha-actin (ASMA), the activation of MAP Kinase (p38-MAPK) and morphological changes consistent with cytoskeletal reorganization. CONCLUSIONS: MK/T-1 cells represent an immortalized fibroblast cell line derived using cultures from corneal stroma cell preparations. Expression of hTERT may contribute to immortalization of the MK/T-1 cells by a mechanism other than increases in RTL. MK/T-1 cells may be a useful model in which to study the responses of corneal fibroblast cells to cytokines and other diverse environmental factors in vitro.

Characterization of Corn1 mice: Alteration of epithelial and stromal cell gene expression.

PURPOSE: Corn1 is an autosomal recessive mutation characterized by corneal epithelial hyperplasia and stromal neovascularization. The aim of the present study is to examine the expression patterns of specific epithelial and stromal proteins in corn/corn1 mutant mice. METHODS: Immunohistochemistry with antibodies directed against keratins 1, 4, 5, 12, and 14 as well as loricrin, filaggrin, and involucrin were performed in corn1/corn1 and wild type, A.By/SnJ strain, mice at 4 weeks of age. Western blot hybridization was performed to confirm the presence of involucrin in corneas. In situ and northern blot hybridization were used to evaluate the expression of keratin 12, lumican, and keratocan in these mice. RESULTS: In corn1/corn1 mice, focal areas of corneal epithelial hyperplasia alternate with epithelium with normal appearance. Both regions of normal and hyperplastic corneal epithelium were labeled by anti-keratin 12 antibodies through all corneal epithelial layers. The anti-keratin 14 antibody only labeled the basal cell layer in normal epithelial areas, whereas it labeled both basal and suprabasal cell layers in hyperplastic areas. In wild type mice, anti-keratin 12 antibodies labeled all corneal epithelial layers, whereas anti-keratin 14 labeled the basal corneal epithelial cells only. Positive staining by anti-involucrin antibody was demonstrated in the basal corneal epithelial layer of wild type mice and normal areas of corn1/corn1 mice. Similarly, as observed with anti-keratin 14 antibody, the anti-involucrin antibody labeled both basal and suprabasal cell layers of hyperplastic corneal epithelium of corn1/corn1 mice. Antibodies against keratin 1, keratin 4, loricrin, and fillagrin did not label the corneas of wild type mice or corn1/corn1 mice. Northern hybridization indicated that the expressions of keratocan and lumican mRNA levels were up regulated in corn1/corn1 mice, but keratin 12 mRNA remained similar to that of the wild type mice. In situ hybridization revealed that the lumican mRNA was detected in epithelial and stromal cells of corn1/corn1 mice, whereas keratocan mRNA was only detected in stromal cells. CONCLUSIONS: Hyperproliferative epithelial cells of corn1/corn1 mice have increased levels of expression of keratin 14 and involucrin, but do not exhibit the phenotypical characteristics of cornification. These observations indicate that factors associated with the phenotypes of corn1/corn1 mice do not alter the cornea-type epithelial differentiation of keratin 12 expression, but cause aberrant expression of lumican by corneal epithelial cells.

Cell density regulates prolyl 4-hydroxylase activity independent of mRNA levels.

In embryonic avian tendon, cell density regulates collagen production. This control is propagated through the alpha-subunit of prolyl 4-hydroxylase where protein levels were previously shown to rise fivefold with increasing cell density. In contrast, mRNA levels are now shown not to change by both Northern and RNAse protection assays. This lack of increase contrasts with previous reports as does the mRNA length: this is 50% larger as confirmed by sequencing the 3' end. Alternative sites for cell density regulation of the enzyme could rely on its sensitivity to sulfhydryl groups. Using a fluorescent sulfhydryl probe as well as a sulfhydryl inhibitor, one observes a strong cell density response, supporting the hypothesis that cellular redox potential could alter protein stability.

Control of SV-40 transformed RCE cell proliferation by growth-factor-induced cell cycle progression.

PURPOSE: To determine in SV40-immortalized rabbit corneal epithelial cells (RCE), whether there is conservation of parent tissue serum growth-factor-stimulated cytokine receptor activation and downstream intracellular signaling events mediating control of cell cycle progression and differentiation. METHODS: Immunostaining and Western blot analysis were used to measure cytokeratin K3 and K12 expression with AE5 and AK12 antibodies. Karyotype analysis was performed based on comparison of the RCE chromosomal complement with its parent tissue. EGF receptor activation was evaluated based on immunochemistry and Western blot analyses of EGF receptor dimerization and phosphorylation. Functional status of EGF receptor was determined through measurements of EGF-induced stimulation of ERK-2 activity, which is a component of the mitogen-activated protein kinase cascade (MAPK). This was done by immunocomplex and kinase assay using anti-ERK antibodies and a specific substrate. EGF-induced increases in proliferation and cell cycle progression were determined based on measurements of [(3)H]-thymidine incorporation, G(2)-specific cyclin B1 expression and cell cycle mapping. RESULTS: From days 7 to 14, K12 expression increased based on marked rises in the levels of a 55 kD band. At day 14, a 64 kD band also appeared indicative of K3 expression. Karyotype analysis showed that there were no chromosomal losses due to SV-40 transformation. Upon exposure to EGF (5 ng/ml) for 1 min, EGF receptors were activated and formed clusters indicating that autophosphorylation and multimerization of the EGF receptor were occurred. In the presence of serum growth factors or EGF, ERK-2 kinase activity was markedly increased with a bell-shaped time-dependent activation pattern. Cell cycle progression was analyzed in G(1)/S boundary synchronized RCE cells. After releasing the cells into modified Supplemented Hormonal Epithelium Medium containing 10% serum and DMEM/F-12 medium, 80% of the cells had entered the S phase within 2 h. In addition, time dependent changes in [(3)H]-hymidine incorporation over 8 h confirmed RCE passage through the G(1)/S checkpoint. There were more RCE cells entered the G(2)/M phase of cell cycle in the 6-8 h interval after their release. Another indication of cell cycle progression into the G(2)/M phase was that at 8-10 h cyclin B(1) expression reached its maximal level. CONCLUSIONS: RCE in passage number 12-20 are a physiologically relevant model for studies on growth factor receptor mediated control of cell cycle progression and differentiation in its parent tissue as each of these phenomena were conserved: 1) EGF-induced EGF receptor activation; 2) EGF-activated ERK signaling; 3) expression of cornea-specific differentiation markers; 4) karyotype profile; and 5) cell cycle control and progression.

TGFbeta2 in corneal morphogenesis during mouse embryonic development.

To examine the roles of TGFbeta isoforms on corneal morphogenesis, the eyes of mice that lack TGFbetas were analyzed at different developmental stages for cell proliferation, migration and apoptosis, and for expression patterns of keratin 12, lumican, keratocan and collagen I. Among the three Tgfb(-/-) mice, only Tgfb2(-/-) mice have abnormal ocular morphogenesis characterized by thin corneal stroma, absence of corneal endothelium, fusion of cornea to lens (a Peters'-like anomaly phenotype), and accumulation of hyaline cells in vitreous. In Tgfb2(-/-) mice, fewer keratocytes were found in stroma that has a decreased accumulation of ECM; for example, lumican, keratocan and collagen I were greatly diminished. The absence of TGFbeta2 did not compromise cell proliferation, nor enhance apoptosis. The thinner stroma resulting from decreased ECM synthesis may account for the decreased cell number in the stroma of Tgfb2 null mice. Keratin 12 expression was not altered in Tgfb2(-/-) mice, implicating normal corneal type epithelial differentiation. Delayed appearance of macrophages in ocular tissues was observed in Tgfb2(-/-) mice. Malfunctioning macrophages may account for accumulation of cell mass in vitreous of Tgfb2 null mice.

Analysis of the human lumican gene promoter.

The human lumican gene was shown to possess one major transcription start site, resulting in exon 1 of the gene giving rise to the first 74 base pairs (bp) of the 5'-untranslated region. About 1.6 kilobase pairs of upstream promoter sequence were sequenced and analyzed to identify elements responsible for gene expression. No typical TATAA sequence was identified in the vacinity of the transcription start site, but an atypical TATCA sequence residing 41 bp upstream was shown to be necessary for transcription, although it was incapable of supporting transcription by itself. A GC box residing 74 bp upstream of the transcription start site also was essential for the initiation of transcription. Sp3 was identified as the transcriptional activator binding to the GC box. No additional elements that significantly modulated transcription were noted in the promoter sequence analyzed, when using human adult chondrocytes as the cell source for transfection in reporter assays. In contrast, reporter assays carried out in human fetal lung fibroblasts, where lumican expression is deplete, revealed the presence of a repressor element located between 384 and 598 bp upstream of the transcription start site. A GATA-binding site located between bp -386 and -391 was identified as being necessary for repression of transcription. The mouse lumican promoter does not possess an equivalent site, and this may explain why the lumican gene is expressed in fetal murine cartilage but not in fetal human cartilage.

Retinal degeneration in cone photoreceptor cell-ablated transgenic mice.

PURPOSE: To examine the effect of loss of cone photoreceptor cells on retinal degeneration. METHODS: We previously identified a cone photoreceptor cell-specific promoter of human cone transducin a-subunit (GNAT2) gene. In this report, a minigene, Trc-Tox176, that contains the GNAT2 promoter, an attenuated diphtheria toxin A-chain gene, and an enhancer element from human interphotoreceptor retinoid-binding protein (IRBP) was used to generate coneless transgenic mice. Transgenic mice were identified by PCR and the copy number of the transgene was determined by Southern hybridization, and examined by histology. RESULTS: The results of immunostaining with anti-mouse GNAT2 antibodies and reverse transcription-PCR (RT-PCR) analysis with mRNA from the retinas of transgenic mice showed that cone photoreceptor cells were ablated in one of four transgenic mouse lines. The ablation of cone cells began at postnatal day 8, at the same time as the expression of endogenous GNAT2. An age-related rod degeneration was also found in this cone-ablated mouse line, beginning at postnatal day 9, proceeding from the central retina to the peripheral retina. CONCLUSIONS: Cone photoreceptor cells may play an important role in the survival of rod photoreceptor cells during mouse retina development.

Identification of a 3.2 kb 5'-flanking region of the murine keratocan gene that directs beta-galactosidase expression in the adult corneal stroma of transgenic mice.

The mouse keratocan gene (Ktcn) expression tracks the corneal morphogenesis during eye development and becomes restricted to keratocytes of the adult, implicating a cornea-specific gene regulation of the mouse Ktcn [J. Biol. Chem., 273 (1998) 22584-22588]. To examine the functionality of the mouse Ktcn promoter, we have cloned and sequenced a 3.2kb genomic DNA fragment 5' of the mouse Ktcn gene, which was used to prepare a reporter gene construct that contained the 3.2kb 5' flanking sequence, exon 1 and 0.4kb of intron 1 of Ktcn, and beta-geo hybrid reporter gene. The beta-galactosidase (betaGal) activity was assayed in tissues of two of five transgenic mouse lines obtained via microinjection. In adult transgenic mice, betaGal activity was detected only in cornea, not in other tissues (e.g. lens, retina, sclera, lung, heart, liver, diaphragm, kidney, and brain). During ocular development, the spatial-temporal expression patterns of the betaGal recapitulated that of endogenous Ktcn in transgenic mice. Using XGal staining, strong betaGal activity was first detected in periocular tissues of E13.5 embryos, and restricted to corneal keratocytes at E14.5 and thereafter. Interestingly, in addition to cornea, betaGal activity was transiently found in some non-ocular tissues, i.e. ears, snout, and limbs of embryos of E13.5 and E14.5 but was no longer detected in those tissues of E16.5 embryos. The transient expression of endogenous keratocan in non-ocular tissues during embryonic development was confirmed by in situ hybridization. Taken together, our results suggest that the 3.2kb Ktcn promoter contains sufficient cis-regulatory elements to drive heterologous minigene expression in cells expressing keratocan. The identification of keratocyte-specific expression of betaGal reporter gene in the adult transgenic mice is an important first step in characterizing the Ktcn promoter in order to use it to drive a foreign gene expression in corneal stroma.

Role of lumican in the corneal epithelium during wound healing.

Lumican regulates collagenous matrix assembly as a keratan sulfate proteoglycan in the cornea and is also present in the connective tissues of other organs and embryonic corneal stroma as a glycoprotein. In normal unwounded cornea, lumican is expressed by stromal keratocytes. Our data show that injured mouse corneal epithelium ectopically and transiently expresses lumican during the early phase of wound healing, suggesting a potential lumican functionality unrelated to regulation of collagen fibrillogenesis, e. g. modulation of epithelial cell adhesion or migration. An anti-lumican antibody was found to retard corneal epithelial wound healing in cultured mouse eyes. Healing of a corneal epithelial injury in Lum(-/-) mice was significantly delayed compared with Lum(+/-) mice. These observations indicate that lumican expressed in injured epithelium may modulate cell behavior such as adhesion or migration, thus contributing to corneal epithelial wound healing.

Impression cytology of pterygium.

The purpose of this study was to study the morphology and cytokeratin expression in the epithelia of pterygia. Impression cytology and immunohistochemical staining with antikeratin antibodies were performed in 32 eyes of 16 patients with pterygia. TUNEL stain and electron microscopy were also performed in surgical specimens ofpterygium. Squamous metaplasia-like epithelial cells were found in all specimens of impression cytology, especially in the head part. These specimens had positive immunostaining by antipancytokeratin antibodies, but not by anti-K12 AK2 mAb. Goblet cells were found around the area of these abnormal epithelial cells. TUNEL-positive cells were found in the epithelia of the pterygial head, but not in the body of pterygia and normal conjunctiva. The expressional patterns of keratin by these epithelial cells ofpterygia are consistent with the notion that they are derived from conjunctival epithelium and mimic the process of squamous metaplasia.

Expression of involucrin by ocular surface epithelia of patients with benign and malignant disorders.

PURPOSE: Keratinization of the ocular surface epithelium is associated with various disorders impairing vision. We immunohistochemically determined whether the ocular surface epithelia express involucrin, and whether its expression pattern may differ in benign vs. malignant disorders. Expression of cytokeratins was also examined to provide further information relative to the epithelial differentiation. METHODS: We evaluated 17 specimens; 6 specimens of the normal ocular surface epithelia, 3 specimens from cases of conjunctival intraepithelial neoplasia (CIN), 6 of conjunctival squamous cell carcinoma (SCC) and 2 of conjunctivae from cases of superior limbic keratoconjunctivitis (SLK). RESULTS: Corneal epithelium exhibited intracellular immunoreactivity for involucrin. Four of the 6 specimens of bulbar conjunctival epithelium showed involucrin immunoreactivity in the perimembranous region, whereas the fornical conjunctiva was negative. Cornified envelope in SLK specimens was positive for involucrin. The CIN showed its immunoreactivity in the perimembranous region in all levels of the hyperproliferative epithelium without keratinization, i.e., similar to the bulbar conjunctiva. The neoplastic cells of well-differentiated SCC showed involucrin in the perimembranous region, and those of moderately- to poorly-differentiated SCC have involucrin in their cytoplasm. The expression pattern of cytokeratins was unrelated to grade of malignancy in ocular SCC. CONCLUSION: The epithelia of normal subjects and of CIN expresses involucrin without keratinization. In contrary, the keratinized SLK epithelium markedly expresses involucrin in the cornified envelope. The subcellular immunolocalization of involucrin in the ocular SCC may help in evaluating the differentiation, i.e., malignancy, of neoplastic cells.

Ectopic gland induction by lens-specific expression of keratinocyte growth factor (FGF-7) in transgenic mice.

During mammalian embryogenesis, epithelial-mesenchymal interactions play a determining role in normal tissue patterning and development. Keratinocyte growth factor (KGF), a member of the fibroblast growth factor (FGF) family, is a mesenchymally-derived mitogen for epithelial cells. As the KGF receptor is expressed by epithelial cells of numerous tissues and KGF is produced in adjacent stromal cells, KGF is thought to play a role in mediating epithelial cell behaviour. To further investigate the role of this molecule in the development of ocular epithelia we employed transgenic mice engineered to overexpress human KGF in the eye. The most striking phenotypic development was the hyperproliferation of embryonic corneal epithelial cells and their subsequent differentiation into functional lacrimal gland-like tissues. This indicates that stimulation of the KGF receptor early in development, in surface ectoderm normally destined to form corneal epithelium, is sufficient to alter the fate of these cells. Furthermore, this suggests that the correct spatial and temporal expression of FGFs plays a critical role in normal lacrimal gland induction. These transgenic mice provide a valuable model system to study the mechanisms underlying cell fate decisions during ocular morphogenesis.

Immunolocalization of transcription factor AP1 in human ocular surface epithelia.

PURPOSE: The present study examined whether normal human ocular surfcae epithelia express AP1 components. Changes in expression patterns of these components in a case of ocular surface epithelial dysplasia was also evaluated before and after topical mitomycin C treatment. METHODS: Specimens of normal corneas (n = 2) and conjunctiva (n = 4) were obtained from 4 patients during cataract surgery or post mortem, while specimens of dysplastic epithelial tissue from the limbus were obtained from one patient. Specimens were immunohistochemically studied using antibodies against components of AP1. RESULTS: The normal corneal epithelium showed no staining with antibodies against c-Fos, Fra-2, FosB, c-Jun or JunB, whereas the limbal and bulbar conjunctival epithelia were positive for c-Fos, Fra-2, and c-Jun. Anti-FosB and -JunB antibodies reacted weakly with the conjunctival epithelium. JunD was absent in normal corneal and conjunctival epithelia. The dsyplastic epithelium showed positive labelling for c-Fos, Fra-2, c-Jun, and JunD throughout its thickness. Fra-1 was present in all specimens of epithelia examined. The dysplastic epithelium treated with mitomycin C was not labeled by anti-c-Fos or -Fra-2 antibody. CONCLUSION: Individual AP1 components show specific expression patterns in normal ocular surface epithelia and a case of dysplastic epithelium before and after topical MMC treatment, implying that these factors may play important roles in modulating epithelial cell function, e.g., proliferation and differentiation.

Transforming growth factor(beta)-mediated corneal myofibroblast differentiation requires actin and fibronectin assembly.

PURPOSE: Recent studies indicate that transforming growth factor (TGF)beta is a potent inducer of corneal myofibroblast differentiation and expression of smooth muscle-specific, alpha-actin (alpha-SMA). Although TGFbeta is known to enhance synthesis of extracellular matrix proteins and receptors, little is known about how it modulates the expression of smooth muscle proteins in nonmuscle cells. The purpose of this study was to identify the role of Arg-Gly-Asp (RGD)-dependent tyrosine phosphorylation in regulating alpha-SMA gene expression and ultimately myofibroblast development. METHODS: Because cell culture in serum-containing media mimics myofibroblast transformation, all experiments were performed on freshly isolated rabbit keratocytes plated in defined, serum-free media. Cells were exposed to TGFbeta (1 ng/ml), Gly-Arg-Gly-Asp-D-Ser-Pro (GRGDdSP, 50 microM), Gly-Arg-AL-Asp-Ser-Pro (GRADSP; 100 microM), or herbimycin A (0.1-10 nM) at 24 hours (sparse) or 7 days (confluent). Cells were evaluated by immunocytochemistry and proteins and RNA collected for western and northern blot analyses using antibodies specific for alpha-SMA, fibronectin, focal adhesion proteins, and phosphotyrosine (clones 4G10 and PY20); and probes directed against rabbit alpha-SMA. All experiments were repeated at least three times. RESULTS: Keratocytes exposed to TGFbeta showed expression of alpha-SMA that coincided with the intracellular reorganization of the actin cytoskeleton and the extracellular assembly of fibronectin fibrils. Addition of RGD containing but not control peptides blocked the organization of intracellular actin, extracellular fibronectin, and alpha-SMA protein and mRNA. Immunoprecipitation of cell proteins with 4G10 or PY20 identified the TGFbeta-associated tyrosine phosphorylation of paxillin, pp125fak, p130, PLCgamma, and tensin, which was blocked by addition of GRGDdSP. Addition of herbimycin A to keratocytes exposed to TGFbeta showed a dose-dependent loss of alpha-SMA protein and mRNA which correlated with loss of tyrosine phosphorylation, absence of actin reorganization, and fibronectin assembly. CONCLUSIONS: The data suggest that TGFbeta-mediated alpha-SMA gene expression leading to myofibroblast transformation may involve an RGD-dependent phosphotyrosine signal transduction pathway.

Immunohistochemical and ultrastructural analysis of dysplastic epithelium of human ocular surface: basement membrane and intermediate filament.

PURPOSE: The dysplastic corneal epithelium is characterized by the abnormal proliferation of epithelial cells. The phenotypes of these cells have not been elucidated. We investigated whether such epithelium expresses the phenotypes of corneal or conjunctival epithelial cells. METHODS: The corneas and conjunctivae from four normal subjects and from one patient with epithelial dysplasia of the central cornea were immunostained for IV and VII collagens and for cytokeratins. Monoclonal antibodies against collagen IV reacted to the [alpha1(IV)]2alpha2(IV) or alpha5(IV) molecule. Anti-cytokeratin antibodies were used to define epithelial cell types. The ultrastructure of the basement membrane (BM) of each specimen also was examined. RESULTS: Type VII collagen immunoreactivity was detected in all the specimens of epithelial BM. The anti-collagen IV [alpha1(IV)]2alpha2(IV) antibody labeled the conjunctival BMs, not the BMs of the corneal epithelia, of each subject. The normal corneal epithelial BM, not the BM of the conjunctival or dysplastic corneal epithelium, was immunolabeled with anti-alpha5(IV) antibody. The pattern of cytokeratin expression in the corneal epithelial dysplasia resembled that seen in the normal conjunctivae. Small breaks in the BM of dysplastic corneal epithelium were ultrastructurally revealed. The number of hemidesmosomes in the dysplastic corneal epithelium was decreased as compared with that in the normal BM. CONCLUSION: The composition of collagen types within the BM and the cellular phenotype of the dysplastic epithelium in the cornea resembled those of conjunctival epithelium, not of the cornea.