Diurnal Variation of Tight Junction Integrity Associates Inversely with Matrix Metalloproteinase Expression in Xenopus laevis Corneal Epithelium: Implications for Circadian Regulation of Homeostatic Surface Cell Desquamation

Background and Objectives

The corneal epithelium provides a protective barrier against pathogen entrance and abrasive forces, largely due to the intercellular junctional complexes between neighboring cells. After a prescribed duration at the corneal surface, tight junctions between squamous surface cells must be disrupted to enable them to desquamate as a component of the tissue homeostatic renewal. We hypothesize that matrix metalloproteinase (MMPs) are secreted by corneal epithelial cells and cleave intercellular junctional proteins extracellularly at the epithelial surface. The purpose of this study was to examine the expression of specific MMPs and tight junction proteins during both the light and dark phases of the circadian cycle, and to assess their temporal and spatial relationships in the Xenopus laevis corneal epithelium.

Methodology/Principal Findings

Expression of MMP-2, tissue inhibitor of MMP-2 (TIMP-2), membrane type 1-MMP (MT1-MMP) and the tight junction proteins occludin and claudin-4 were examined by confocal double-label immunohistochemistry on corneas obtained from Xenopus frogs at different circadian times. Occludin and claudin-4 expression was generally uniformly intact on the surface corneal epithelial cell lateral membranes during the daytime, but was frequently disrupted in small clusters of cells at night. Concomitantly, MMP-2 expression was often elevated in a mosaic pattern at nighttime and associated with clusters of desquamating surface cells. The MMP-2 binding partners, TIMP-2 and MT1-MMP were also localized to surface corneal epithelial cells during both the light and dark phases, with TIMP-2 tending to be elevated during the daytime.

Conclusions/Significance

MMP-2 protein expression is elevated in a mosaic pattern in surface corneal epithelial cells during the nighttime in Xenopus laevis, and may play a role in homeostatic surface cell desquamation by disrupting intercellular junctional proteins. The sequence of MMP secretion and activation, tight junction protein cleavage, and subsequent surface cell desquamation and renewal may be orchestrated by nocturnal circadian signals.     

Circadian variations in the DNA synthesis of the rat corneal epithelium. A study using double labelling with tritiated thymidine

A prominent circadian rhythm was found in the labelling indices (LI) of the peripheral rat corneal epithelium and of the adjacent conjunctival epithelium, while almost no diurnal variation was found in the central area. Application of a double labelling technique indicated that there are rhythmic pulses of high and low influx of cells into the S phase and similar pulses of efflux of cells from the S phase. Results of the study indicate that there are different cohorts of cycling cells all over the rat corneal epithelium. Cells belonging to a rapidly proliferating cohort are observed in the peripheral cornea. There is a gradual reduction in the fraction of labelled DNA-synthesizing cells towards the centre. The considerably lower fraction of cells taking up tritiated thymidine (3H)TdR in the central cornea may be due to a higher fraction of basal cells having reached higher levels of differentiation. This may result in a shift from the salvage to the de novo pathway. The slowly proliferating cohort seems to have a prolonged S phase duration and displays practically no diurnal variation in the LI. The DNA-synthesizing cells belonging to this latter cohort probably use the salvage pathway for DNA synthesis resulting in uptake of (3H)TdR all over the cornea. The LI is thus not a reliable indicator of cell proliferation in the corneal epithelium, due both to the heterogeneity of the cell proliferation, and in particular due to the lack of labelling of the centrally located DNA-synthesizing cells. To what extent these properties may also be present in other proliferating tissues with different levels of differentiations, may be questioned.     

Further studies on the biological characteristics of an endogenous colon mitosis inhibitor: Comparison with some structurally related peptides

Previous work indicates that the colonic epithelial cell proliferation in mice is reversibly inhibited by the tripeptide pGlu-His-GlyOH found in aqueous extracts of the intestine. In the present study we examined the possible tissue specificity of the colon mitosis inhibitor. The mitotic rate in the small intestine, epidermis and forestomach in mice was registered after a single i.p. injection of the tripeptide. A significantly reduced rate of cell renewal was found at 18 h in the epidermis whereas no inhibition was observed in the forestomach or ileal epithelium. To investigate whether the amino acid sequence of the tripeptide is essential for the inhibitory effect, three structurally related bioactive peptides were tested and compared to the effect of CMI. CMI showed a bell-shaped dose-response relationship as previously shown, whereas the mitotic rate was not reduced in the colonie epithelium after treatment with either an epidermal mitosis inhibitory pentapeptide, or the dipeptide pGlu-GlyOH, or an analogue of luteinizing hormone-releasing hormone. The efficacy of the tripeptide was dependent on the basal rate of cell renewal in the colonie epithelium. When the tripeptide was given at the circadian nadir of cell proliferation a delayed reduction of the proliferative activity was observed at 6 h after treatment, whereas treatment when the rate of cell proliferation was at its circadian zenith gave an immediate mitotic inhibition.     

Further studies on the biological characteristics of an endogenous colon mitosis inhibitor: comparison with some structurally related peptides

Previous work indicates that the colonic epithelial cell proliferation in mice is reversibly inhibited by the tripeptide pGlu-His-GlyOH found in aqueous extracts of the intestine. In the present study we examined the possible tissue specificity of the colon mitosis inhibitor. The mitotic rate in the small intestine, epidermis and forestomach in mice was registered after a single i.p. injection of the tripeptide. A significantly reduced rate of cell renewal was found at 18 h in the epidermis whereas no inhibition was observed in the forestomach or ileal epithelium. To investigate whether the amino acid sequence of the tripeptide is essential for the inhibitory effect, three structurally related bioactive peptides were tested and compared to the effect of CMI. CMI showed a bell-shaped dose-response relationship as previously shown, whereas the mitotic rate was not reduced in the colonic epithelium after treatment with either an epidermal mitosis inhibitory pentapeptide, or the dipeptide pGlu-GlyOH, or an analogue of luteinizing hormone-releasing hormone. The efficacy of the tripeptide was dependent on the basal rate of cell renewal in the colonic epithelium. When the tripeptide was given at the circadian nadir of cell proliferation a delayed reduction of proliferative activity was observed at 6 h after treatment, whereas treatment when the rate of cell proliferation was at its circadian zenith gave an immediate mitotic inhibition.     

Symmetric and asymmetric cell division in rat corneal epithelium

Mitotic cells in normal, mature rat corneal epithelium were examined with a light microscope on serial, semi-thick plastic sections. Classification of mitotic figures into horizontally, obliquely or vertically positioned with reference to the epithelial basal lamina has shown that no single configuration predominates. A striking correlation between the position of the daughter cells after cytokinesis and their morphology has been observed. Horizontal cytokinetic pairs were morphologically symmetric but vertical ones were asymmetric, displaying distinct differences between daughter cells. Analysis of earlier mitotic phases has shown that the asymmetry could also be observed in vertical anaphases and telophases. The data provide clear morphological evidence for real asymmetric (unequal) cell division in a replacing epithelium in an adult mammal. It is concluded that asymmetric cell division in the corneal epithelium coexists with, and is as frequent as symmetric (equal) cell division. Randomness of mitotic spindle positioning implies that diverse forms of cell transfer from the proliferative into the differentiative epithelial compartments must operate. Therefore, the universality of the general model of cell renewal in stratified epithelia, which assumes a strong predominance of horizontal mitoses, exclusively equal mitotic divisions and one form of cell transfer, is questioned.     

Effects of acyclic analogs of atrial natriuretic factor on proliferative processes of the epithelial tissue in white rats]

The effect of atrial natriuretic factor (ANF) synthetic linear truncated analogues AP-H-6-OH and AP-FOR-6-OH on corneal, skin, duodenum and colon epithelium proliferation has been studied on male rats. The epithelium mitotic activity and DNA synthesis were evaluated 4 and 24 h after intraperitoneal injection of 10 or 100 micrograms/kg peptides. In a dose of 10 micrograms/kg both ANF synthetic analogues inhibited proliferation processes in corneal epithelium, but activated the DNA synthesis in duodenum and colon epithelium. AP-FOR-6-OH (10 micrograms/kg) decreased the mitotic activity of skin epithelium and increased the silver grain density over the cell nuclei at the same time. 100 micrograms/kg ANF analogues stimulated cell mitogenesis in all organs studied. According to the data obtained ANF linear truncated analogues influence on epithelium proliferation is similar to effector of previously studied cyclic atriopeptin AP II.     

Symmetric and asymmetric cell division in rat corneal epithelium

Abstract. Mitotic cells in normal, mature rat corneal epithelium were examined with a light microscope on serial, semi-thick plastic sections.
Classification of mitotic figures into horizontally, obliquely or vertically positioned with reference to the epithelial basal lamina has shown that no single configuration predominates. A striking correlation between the position of the daughter cells after cytokinesis and their morphology has been observed. Horizontal cytokinetic pairs were morphologically symmetric but vertical ones were asymmetric, displaying distinct differences between daughter cells. Analysis of earlier mitotic phases has shown that the asymmetry could also be observed in vertical anaphases and telophases.
The data provide clear morphological evidence for real asymmetric (unequal) cell division in a replacing epithelium in an adult mammal. It is concluded that asymmetric cell division in the corneal epithelium coexists with, and is as frequent as symmetric (equal) cell division. Randomness of mitotic spindle positioning implies that diverse forms of cell transfer from the proliferative into the differentiative epithelial compartments must operate. Therefore, the universality of the general model of cell renewal in stratified epithelia, which assumes a strong predominance of horizontal mitoses, exclusively equal mitotic divisions and one form of cell transfer, is questioned.     

Discrepancies between cell volume and organic content in semi-continuous cultures of a marine microalga

J. FÁBREGAS, A. CID, E. MORALES, B. CORDERO AND A. OTERO. 1996. Changes in average cell volume, measured by flow cytometry, and cell organic content were studied in light/dark synchronized semi-continuous cultures of the marine microalga Phaeodactylum tricornutum . Cell volume and organic content both increased with nutrient concentration at all the renewal rates tested. Cell volume against renewal rate, at each nutrient concentration, followed a U-shaped curve with smallest cells at intermediate renewal rates. In contrast, cell organic content decreased continuously with increasing renewal rate. The variation in cell volume and organic content, related to culture conditions, should be taken into account if biochemical composition and productivity of microalgal cultures are assessed on the basis of cell counts.     

Chromosome constancy in the corneal epithelium of the mouse

Summary A cell-to-cell variation in chromosome number (somatic inconstancy) is said to occur in some mammalian tissues. The polyploid element of this inconstancy appears to be well established, particularly for the liver, the blood, and in deciduomata. The reality of the aneuploid element has been disputed, and recent work has shown that the range and frequency of this variation must be considerably less than previously reported. The present work permits a positive statement about one mammalian tissue; in mitoses from the corneal epithelium of the mouse, constancy of chromosome number from cell to cell is virtually absolute. It is suggested that material for checking the existence of aneuploid inconstancy should be sought among differentiated tissues. The combination of technique and tissue used provides mitoses rivalling in clarity and abundance those obtainable from the testis, and may constitute a general method for assessing the diploid chromosome number of either sex in mammals. The centromere appears to be sub-terminal in most if not all of the chromosomes from the corneal epithelium of the mouse.Member of Agricultural Research Council Staff.     

Corneal epithelial cell fate is maintained during repair by Notch1 signaling via the regulation of vitamin A metabolism

Integrity and preservation of a transparent cornea are essential for good vision. The corneal epithelium is stratified and nonkeratinized and is maintained and repaired by corneal stem cells. Here we demonstrate that Notch1 signaling is essential for cell fate maintenance of corneal epithelium during repair. Inducible ablation of Notch1 in the cornea combined with mechanical wounding show that Notch1-deficient corneal progenitor cells differentiate into a hyperplastic, keratinized, skin-like epithelium. This cell fate switch leads to corneal blindness and involves cell nonautonomous processes, characterized by secretion of fibroblast growth factor-2 (FGF-2) through Notch1(-/-) epithelium followed by vascularization and remodeling of the underlying stroma. Vitamin A deficiency is known to induce a similar corneal defect in humans (severe xerophthalmia). Accordingly, we found that Notch1 signaling is linked to vitamin A metabolism by regulating the expression of cellular retinol binding protein 1 (CRBP1), required to generate a pool of intracellular retinol.     

Expression of semaphorin 3A in the rat corneal epithelium during wound healing

The neural guidance protein semaphorin 3A (Sema3A) is expressed in corneal epithelial cells of the adult rat. We have now further investigated the localization of Sema3A in the normal rat corneal epithelium as well as changes in its expression pattern during wound healing after central corneal epithelial debridement. The expression pattern of Sema3A was compared with that of the tight-junction protein zonula occludens-1 (ZO-1), the gap-junction protein connexin43 (Cx43), or the cell proliferation marker Ki67. Immunofluorescence analysis revealed that Sema3A was present predominantly in the membrane of basal and wing cells of the intact corneal epithelium. The expression of Sema3A at the basal side of basal cells was increased in the peripheral epithelium compared with that in the central region. Sema3A was detected in all layers at the leading edge of the migrating corneal epithelium at 6 h after central epithelial debridement. The expression of Sema3A was markedly up-regulated in the basal and lateral membranes of columnar basal cells apparent in the thickened, newly healed epithelium at 1 day after debridement, but it had largely returned to the normal pattern at 3 days after debridement. The expression of ZO-1 was restricted to superficial epithelial cells and remained mostly unchanged during the wound healing process. The expression of Cx43 in basal cells was down-regulated at the leading edge of the migrating epithelium but was stable in the remaining portion of the epithelium. Ki67 was not detected in basal cells of the central epithelium at 1 day after epithelial debridement, when Sema3A was prominently expressed. Immunoblot analysis showed that the abundance of Sema3A in the central cornea was increased 1 day after epithelial debridement, whereas that of ZO-1 or Cx43 remained largely unchanged. This increase in Sema3A expression was accompanied by up-regulation of the Sema3A coreceptor neuropilin-1. Our observations have thus shown that the expression of Sema3A is increased markedly in basal cells of the newly healed corneal epithelium, and that this up-regulation of Sema3A is not associated with cell proliferation. They further suggest that Sema3A might play a role in the regulation of corneal epithelial wound healing.     

Stem cells in the eye

In the adult organism, all tissue renewal and regeneration depends ultimately on somatic stem cells, and the eye is no exception. The importance of limbal stem cells in the maintenance of the corneal epithelium has long been recognised, and such cells are now used clinically for repair of a severely damaged cornea. The slow cycling nature of lens epithelial cells and their ability to terminally differentiate into fiber cells are suggestive of a stem cell lineage. Furthermore, recent studies have identified progenitor cells in the retina and ocular vasculature which may have important implications in health and disease. Although the recent literature has become flooded with articles discussing aspects of stem cells in a variety of tissues our understanding of stem cell biology, especially in the eye, remains limited. For instance, there is no definitive marker for ocular stem cells despite a number of claims in the literature, the patterns of stem cell growth and amplification are poorly understood and the microenvironments important for stem cell regulation and differentiation pathways are only now being elucidated. A greater understanding of ocular stem cell biology is essential if the clinical potential for stem cells is to be realised. For instance; How do we treat stem cell deficiencies? How do we use stem cells to regenerate damaged retinal tissue? How do we prevent stem cell lineages contributing to retinal vascular disease? This review will briefly consider the principal stem cells in the mature eye but will focus in depth on limbal stem cells and corneal epithelium. It will further discuss their role in pathology and their potential for therapeutic intervention.     

Deletion of JAM-A causes morphological defects in the corneal epithelium

Junctional adhesion molecule-A (JAM-A, JAM-1, F11R) is an Ig domain containing transmembrane protein that has been proposed to function in diverse processes including platelet activation and adhesion, leukocyte transmigration, angiogenesis, epithelial cell shape and endothelial cell migration although its function in vivo is less well established. In the mouse eye, JAM-A protein expression is first detected at 12.5 dpc in the blood vessels of the tunica vasculosa, while it is first detected in both the corneal epithelium and lens between 13.5 and 14.5 dpc. In the corneal epithelium, JAM-A levels remain appreciable throughout life, while JAM-A immunostaining becomes stronger in the lens as the animals age. Both the cornea and lens of mice lacking an intact JAM-A gene are transparent until at least a year of age, although the cells of the JAM-A null corneal epithelium are irregularly shaped. In wild-type mice, JAM-A protein is found at the leading edge of repairing corneal epithelial wounds, however, corneal epithelial wound repair was qualitatively normal in JAM-A null animals. In summary, JAM-A is expressed in the corneal epithelium where it appears to regulate cell shape.     

Amnion and ocular surface problems

The amniotic membrane, the most internal placental membrane, has various properties useful in ophthalmology. Collected on delivery by elective Caesarean section, the amnion is prepared under sterile conditions, and, usually, cryopreserved until its use as a biological bandage or as a substrate for epithelial growth in the management of various ocular surface conditions. Specifically, the amnion is used to : (1) limit formation of adhesive bands between eyelids and eyeball (symblepharon) or the progression of a fibrovascular outgrowth towards the cornea (pterygium) or to (2) facilitate the healing of corneal ulcers, bullous keratopathy, and corneal stem cell deficiency. In this last condition, either hereditary or acquired after a thermal or a chemical burn, corneal stem cells, located at a transitional zone between the cornea and conjunctiva, are lost. These cells are essential for renewal of corneal epithelium in normal and in diseased states. The loss of these cells leaves the corneal surface free for invasion by conjunctival epithelium. Not only, does conjunctival epithelium support the development of vascularisation on the normally avascular cornea, but some conjunctival cells differentiate into mucus secreting goblet cells. Such a change in phenotype leads to loss of corneal transparency and visual disability. The removal of this fibro-vascular outgrowth in combination with transplantation of both amniotic membrane and corneal stem cells are used to treat this condition. The amnion stimulates the proliferation of less differentiated cells which have the potential to reconstruct the cornea. This potential is at the origin of the hypothesis that the amnion may provide an alternative niche for limbal stem cells of the corneal epithelium. It abounds in cytokines and has antalgic, anti-bacterial, anti-inflammatory and anti-immunogenic properties, in addition to allowing, like fetal skin does, wound healing with minimal scar formation. These desirable properties are responsible for the increasing use of amniotic membrane in ophthalmology. The complete understanding of the mechanisms of action of amniotic membrane for ocular surface diseases has yet to be understood. Once revealed by research, they may provide new pharmacological avenues to treat ocular surface diseases.     

Cell proliferation in mouse tissues after thymectomy and the administration of T-activin

The epithelium of mouse cornea and lymph nodes was examined for DNA-synthetic and mitotic activity at different times after thymectomy and administration of T-activin, an active factor of the thymus. Thymectomy entails retardation of the rate of corneal epithelium regeneration, diminution in both tissues under study of the amplitude of oscillations in cell proliferation throughout the day. Administration to the animals of the immunoactive thymic factor T-activin makes the circadian rhythm of cell proliferation return to normal. It is assumed that T-activin raises the capacity of lymphocytes to interact with epithelial cells, which manifests itself in the enhancement of their mitotic activity.     

超声乳化白内障手术后患者角膜内皮细胞损伤的研究

目的:探讨超声乳化白内障手术患者角膜内皮细胞的损伤情况。方法:收集我院确诊为白内障的患者121例,随机分配为微切口组与常规切口组。常规切口组采用3.0 mm切口超声乳化白内障手术方案,微切口组采用1.8 mm小切口超声乳化白内障手术。手术前、手术后1日、7日、1个月、3个月监测患者角膜内皮细胞密度、六角形细胞比例、角膜内皮细胞变异系数及中央角膜厚度。结果:与治疗前相比,两组患者手术后1日、7日、1个月、3个月的角膜内皮细胞密度、六角形细胞比例及角膜内皮细胞变异系数均较治疗前显著降低(P0.05);手术后1日、7日时,两组患者的中央角膜厚度均较手术前明显变薄,有统计学差异(P0.05);手术后1个月、3个月,两组患者的中央角膜厚度均呈降低趋势,最终与手术前相似。微切口组患者不同时点六角形细胞比例与同期常规切口组比较均显著升高,角膜内皮细胞变异系数与同期常规切口组比较均明显降低有统计学差异(P0.05)。两组患者手术前后不同时间点角膜内皮细胞密度、中央角膜厚度组间比较均无统计学差异(P0.05)。结论:超声乳化白内障手术后患者角膜内皮细胞损伤与手术切口有相关性,缩小手术面积的小切口手术使术后修复增快,安全有效,适宜临床推广。     

A comparison of lyophilized amniotic membrane with cryopreserved amniotic membrane for the reconstruction of rabbit corneal epithelium

Many researchers have employed cryopreserved amniotic membrane (CAM) in the treatment of a severely damaged cornea, using corneal epithelial cells cultured on an amniotic membrane (AM). In this study, two Teflon rings were made for culturing the cells on the LAM and CAM, and were then used to support the AM, which is referred to in this paper as an Ahn’s AM supporter. The primary corneal epithelial cells were obtained from the limbus, using an explantation method. The corneal epithelium could be reconstructed by culturing the third-passage corneal epithelial cells on the AM. A lyophilized amniotic membrane (LAM) has a higher rate of graft take, a longer shelf life, is easier to store, and safer, due to gamma irradiation, than a CAM. The corneal epithelium reconstructed on the LAM and CAM, supported by the two-Teflon rings, was similar to normal corneal epithelium. However, the advantages of the LAM over that of the CAM make the former more useful. The reconstruction model of the corneal epithelium, using AM, is considered as a goodin vitro model for transplantation of cornel epithelium into patients with a severely damaged cornea.     

Circardian rhythm of mitoses in the epithelium of the cornea after splenectomy]

In corneal epithelium of CBA mice the index of colchicine mitoses diminished after splenectomy in the day period characterized by rising mitotic activity in control animals. The duration of active phase of cell division rhythm shortened while the maximum of mitotic activity delayed in comparison with control animals. The total amount of cells entering mitosis during 24 hours diminished by 27.7% and the rate of physiological regeneration of corneal epithelium decreased.     

Corneal epithelium as a platform for secretion of transgene products after transfection with liposomal gene eyedrops

BACKGROUND: The first objective of the study was to evaluate the transfection of corneal epithelium with non-viral vectors to secrete transgene products into the tear fluid and aqueous humor. The second goal was to evaluate the differentiated corneal epithelial cell culture for transfection studies. METHODS: The human corneal epithelial (HCE) cell line was cultured to different stages of differentiation and transfected with complexes of pCMV-SEAP2 with DOTAP/DOPE, DOTAP/DOPE/protamine sulfate (PS) and polyethylenimine (PEI). The complexes of DOTAP/DOPE with plasmid (CMV-SEAP2 or pCMV-Luc4) were subsequently applied topically to the rabbit eyes. Secreted alkaline phosphatase (SEAP) was analyzed using chemiluminescent assay. Luciferase (Luc) was detected at the mRNA level in cornea and conjunctiva using a qRT-PCR. RESULTS: The transfection levels decreased with differentiation of HCE cells. PEI was effective in transfecting both the dividing and partly differentiated cells, but ineffective in differentiated cells. DOTAP/DOPE showed high activity in differentiated cell cultures, while added PS did not improve transfection. Significant SEAP expression was observed for three days after in vivo transfection in the tear fluid and aqueous humor. The luciferase mRNA was found both in the cornea and conjunctiva. The rates of SEAP secretion from both the basolateral side of differentiated HCE cells and cornea in vivo were within the same range. CONCLUSIONS: Corneal epithelium can be transfected topically to secrete gene products to the tear fluid and aqueous humor. The differentiated HCE model is a useful tool in the evaluation of non-viral carriers for corneal transfection.