Cellular changes in cultured lenses.

Observations were made on the frog lens epithelium after culture of the entire lens or of capsular explants. General deviations from normal lens structure as well as specific changes in two media were studied. DNA synthesis and mitosis were induced in the central epithelial cells. Disruption of the orderly, single, epithelial layer that is characteristic of normal lenses was accompanied by the appearance of multilayered plaques of epithelial cells and invasion of vacuolated regions of the lens fibers by epithelial cells. Cells that are fibroblast-like in appearance were observed in regions of the capsule depleted of cells and at the free edges of epithelial sheets in cell culture. Epithelial cells were surrounded by capsule-like material even situated in the lens interior. Nuclie derived from central epithelial cells of lenses cultured in L-15 medium and medium 199 had served as donors in previous nuclear transfer experiments in this laboratory. In our current observation of L-15-cultured lenses, cells were sparsely distributed on the capsule and nuclei were abnormally shaped; in 199-cultured lenses, cells were more densely distributed and nuclei resembled those of normal lenses. Medium 199 without serum could better maintain normal lens structure than L-15 medium without serum. In addition, the percentage of epithelial explants demonstrating cellular outgrowth was greater in medium 199. The differences in cellular behavior were shown not to be the result of different sugars, pH, or the presence of CO2. The nuclear transfer results may reflect the structural changes in the epithelium after lens culture in the two media.     

Cellular changes in cultured lenses

Summary Observations were made on the frog lens epithelium after culture of the entire lens or of capsular explants. General deviations from normal lens structure as well as specific changes in two media were studied. DNA synthesis and mitosis were induced in the central epithelial cells. Disruption of the orderly, single, epithelial layer that is characteristic of normal lenses was accompanied by the appearance of multilayered plaques of epithelial cells and invasion of vacuolated regions of the lens fibers by epithelial cells. Cells that are fibroblast-like in appearance were observed in regions of the capsule depleted of cells and at the free edges of epithelial sheets in cell culture. Epithelial cells were surrounded by capsule-like material even when situated in the lens interior. Nuclei derived from central epithelial cells of lenses cultured in L-15 medium and medium 199 had served as donors in previous nuclear transfer experiments in this laboratory. In our current observation of L-15-cultured lenses, cells were sparsely distributed on the capsule and nuclei were abnormally shaped; in 199-cultured lenses, cells were more densely distributed and nuclei resembled those of normal lenses. Medium 199 without serum could better maintain normal lens structure than L-15 medium without serum. In addition, the percentage of epithelial explants demonstrating cellular outgrowth was greater in medium 199. The differences in cellular behavior were shown not to be the result of different sugars, pH, or the presence of CO₂. The nuclear transfer results may reflect the structural changes in the epithelium after lens culture in the two media. This work was supported by grants 2RO1 EY 00555-06 and 5SO1 RR 05510-10 from the National Institutes of Health.     

Cyclic cuanosine 3'5' phosphate, guanylate cyclase and cyclic guanosine phosphodiesterase in the eye lens

While cGMP levels of rat lenses are in the range of those of other tissues, in calf lenses their values are much lower. Guanylate cyclase activities are rather high in proliferating epithelial cells of the lens and decrease strongly with cell differentiation and aging. cGMP phosphodiesterase activities are also reduced with aging in lens epithelial cells. A slight increase seems present in differentiated cortical fibers.     

Contrasting roles for c-Myc and L-Myc in the regulation of cellular growth and differentiation in vivo.

Although myc family genes are differentially expressed during development, their expression frequently overlaps, suggesting that they may serve both distinct and common biological functions. In addition, alterations in their expression occur at major developmental transitions in many cell lineages. For example, during mouse lens maturation, the growth arrest and differentiation of epithelial cells into lens fiber cells is associated with a decrease in L- and c-myc expression and a reciprocal rise in N-myc levels. To determine whether the down-regulation of L- and c-myc are required for mitotic arrest and/or completion of differentiation and whether these genes have distinct or similar activities in the same cell type, we have studied the consequences of forced L- and c-myc expression in the lens fiber cell compartment using the alpha A-crystallin promoter in transgenic mice (alpha A/L-myc and alpha A/c-myc mice). With respect to morphological and molecular differentiation, alpha A/L-myc lenses were characterized by a severely disorganized lens fiber cell compartment and a significant decrease in the expression of a late-stage differentiation marker (MIP26); in contrast, differentiation appeared to be unaffected in alpha A/c-myc mice. Furthermore, an analysis of proliferation indicated that while alpha A/L-myc fiber cells withdrew properly from the cell cycle, inappropriate cell cycle progression occurred in the lens fiber cell compartment of alpha A/c-myc mice. These observations indicate that continued late-stage expression of L-myc affected differentiation processes directly, rather than indirectly through deregulated growth control, whereas constitutive c-myc expression inhibited proliferative arrest, but did not appear to disturb differentiation. As a direct corollary, our data indicate that L-Myc and c-Myc are involved in distinct physiological processes in the same cell type.     

Corneal Cell Adhesion to Contact Lens Hydrogel Materials Enhanced via Tear Film Protein Deposition

Tear film protein deposition on contact lens hydrogels has been well characterized from the perspective of bacterial adhesion and viability. However, the effect of protein deposition on lens interactions with the corneal epithelium remains largely unexplored. The current study employs a live cell rheometer to quantify human corneal epithelial cell adhesion to soft contact lenses fouled with the tear film protein lysozyme. PureVision balafilcon A and AirOptix lotrafilcon B lenses were soaked for five days in either phosphate buffered saline (PBS), borate buffered saline (BBS), or Sensitive Eyes Plus Saline Solution (Sensitive Eyes), either pure or in the presence of lysozyme. Treated contact lenses were then contacted to a live monolayer of corneal epithelial cells for two hours, after which the contact lens was sheared laterally. The apparent cell monolayer relaxation modulus was then used to quantify the extent of cell adhesion to the contact lens surface. For both lens types, lysozyme increased corneal cell adhesion to the contact lens, with the apparent cell monolayer relaxation modulus increasing up to an order of magnitude in the presence of protein. The magnitude of this increase depended on the identity of the soaking solution: lenses soaked in borate-buffered solutions (BBS, Sensitive Eyes) exhibited a much greater increase in cell attachment upon protein addition than those soaked in PBS. Significantly, all measurements were conducted while subjecting the cells to moderate surface pressures and shear rates, similar to those experienced by corneal cells in vivo.     

GROWTH OF LENS AND OCULAR ENVIRONMENT: ROLE OF NEURAL RETINA IN THE GROWTH OF MOUSE LENS AS REVEALED BY AN IMPLANTATION EXPERIMENT

The lens of 6-day-old normal mouse was implanted into the lentectomized eye of adult mouse to examine the effect of retina upon the growth of the implanted lens in vivo. The implanted lens grew normally and its transparency was kept for more than 5 months after implantation. The connection between the implanted lens and the ciliary part of the recipient iris was well established with the regeneration of zonular fibers from the recipient. In young lenses implanted reversely into adult eyes, the epithelial cells facing the retina elongated and a new epithelium was formed on the corneal side of the lens within 5 days. Young lenses implanted either in normal or reverse orientation into eyes from which the retina was previously removed did not grow. The cells of the original lens epithelium of these lenses were randomly accumulated beneath the posterior lens capsule, while the anterior portion of the implanted lenses became an epithelial structure without cell elongation. These results suggest that the growth of the implanted lens may be dependent on the retina of the adult eye.     

Cytoskeletal and contractile structures in bovine lens cell differentiation

Bovine lenses from animals of different ages were separated into two epithelial sections, a cortical region and the lens nucleus. Both the 10000 g supernatant fraction and pellet of these sections were analysed by electrophoresis in SDS-containing polyacrylamide gels. When comparing total protein patterns of the cytoskeletal preparations from the different parts of lenses of different ages a decrease in the amount of vimentin, the protein subunit of lens intermediate-sized filaments (IF), was observed upon lens cell differentiation and aging. Amounts of monomeric (G) and filamentous (F) actin in the different stages of lens cell differentiation were quantitated using the DNase I inhibition technique. A significant increase in the relative amount of F-actin was observed upon fibre cell formation. A slight, but significant increase in the total amount of actin relative to the total amount of cellular protein was observed when passing from the central part of the lens epithelium to the epithelial cells in the elongation zone. In the fibre cells the amount of total actin decreased from cortex to nucleus. A possible function of microfilament-assembly in the process of lens cell differentiation is suggested.     

Developmental analysis of the eye lens obsolescence (Elo) gene in the mouse: cell proliferation and Elo gene expression in the aggregation chimera.

This study investigates the primary effect of the eye lens obsolescence (Elo) gene of the mouse. Morphological features of the Elo lens were defined as follows: (1) deficient elongation of lens fiber cells, (2) morphological abnormality of nuclei of lens fiber cells, (3) lack of eosinophilic granules in the central fiber cells and (4) rupture of lens capsule in the posterior region. We have immunohistologically examined, by means of an in vivo BrdU incorporation system, whether or not the Elo gene regulates cell proliferation during lens development. The lens fiber cells were morphologically abnormal in day 13 embryonic Elo lens. However, there were no significant differences in morphology or cell proliferation between normal and Elo lens epithelium until day 14 of gestation. After day 15, the total cell number in the Elo lens epithelium was significantly less than that in the normal, but the total numbers of S-phase cells in the two genotypes were not significantly different. The ratio of the total S-phase cell number to the total number of lens epithelial cells may be affected by the developmental stage, but not directly by the genotype. The genotype, however, may be having a direct influence at later ages because malformation of Elo lens fiber cells must cause reduction of the total number of lens epithelial cells in older embryos. Although, at 30 days old, Elo lens cells were externally extruded through the ruptured capsule into the vitreous cavity, BrdU-labelled lens epithelial cells were detectable. To investigate whether the Elo lens phenotype is determined by its own genotype or by its cellular environment, we produced aggregation chimeras between C3H-Elo/+(C/C) and BALB/c(c/c). Most lenses of BALB/c dominant chimeras were oval in shape without the ruptured lens capsule. However, they were opaque in the center and slightly smaller in size than normal. The lenses of C3H-Elo/+ dominant chimeras were morphologically similar to the Elo lens. Although normal nuclei were regularly arranged in the anterior region, Elo-type nuclei were located in the posterior region. Immunohistological staining by using anti-C3H strain-specific antibody demonstrated that the lens fiber cells with abnormal nuclei were derived only from C3H-Elo/+, not from BALB/c. These observations suggest that the primary effect of the Elo gene in the developing lens may be specific to the fiber cell differentiation rather than to the cell proliferation.(ABSTRACT TRUNCATED AT 400 WORDS)     

Tropomodulin 1 constrains fiber cell geometry during elongation and maturation in the lens cortex

Lens fiber cells exhibit a high degree of hexagonal packing geometry, determined partly by tropomodulin 1 (Tmod1), which stabilizes the spectrin-actin network on lens fiber cell membranes. To ascertain whether Tmod1 is required during epithelial cell differentiation to fiber cells or during fiber cell elongation and maturation, the authors quantified the extent of fiber cell disorder in the Tmod1-null lens and determined locations of disorder by confocal microscopy and computational image analysis. First, nearest neighbor analysis of fiber cell geometry in Tmod1-null lenses showed that disorder is confined to focal patches. Second, differentiating epithelial cells at the equator aligned into ordered meridional rows in Tmod1-null lenses, with disordered patches first observed in elongating fiber cells. Third, as fiber cells were displaced inward in Tmod1-null lenses, total disordered area increased due to increased sizes (but not numbers) of individual disordered patches. The authors conclude that Tmod1 is required first to coordinate fiber cell shapes and interactions during tip migration and elongation and second to stabilize ordered fiber cell geometry during maturation in the lens cortex. An unstable spectrin-actin network without Tmod1 may result in imbalanced forces along membranes, leading to fiber cell rearrangements during elongation, followed by propagation of disorder as fiber cells mature.     

Unfolded Protein Response (UPR) is activated during normal lens development

The lens of the eye is a transparent structure responsible for focusing light onto the retina. It is composed of two morphologically different cell types, epithelial cells found on the anterior surface and the fiber cells that are continuously formed by the differentiation of epithelial cells at the lens equator. The differentiation of an epithelial precursor cell into a fiber cell is associated with a dramatic increase in membrane protein synthesis. How the terminally differentiating fiber cells cope with the increased demand on the endoplasmic reticulum for this membrane protein synthesis is not known. In the present study, we have found evidence of Unfolded Protein Response (UPR) activation during normal lens development and differentiation in the mouse. The ER-resident chaperones, immunoglobulin heavy chain binding protein (BiP) and protein disulfide isomerase (PDI), were expressed at high levels in the newly forming fiber cells of embryonic lenses. These fiber cells also expressed the UPR-associated molecules; XBP1, ATF6, phospho-PERK and ATF4 during embryogenesis. Moreover, spliced XBP1, cleaved ATF6, and phospho-eIF2α were detected in embryonic mouse lenses suggesting that UPR pathways are active in this tissue. These results propose a role for UPR activation in lens fiber cell differentiation during embryogenesis.     

Bone morphogenetic protein signaling and the initiation of lens fiber cell differentiation

Previous studies showed that the retina produces factors that promote the differentiation of lens fiber cells, and identified members of the fibroblast growth factor (FGF) and insulin-like growth factor (IGF) families as potential fiber cell differentiation factors. A possible role for the bone morphogenetic proteins (BMPs) is suggested by the presence of BMP receptors in chicken embryo lenses. We have now observed that phosphorylated SMAD1, an indicator of signaling through BMP receptors, localizes to the nuclei of elongating lens fiber cells. Transduction of chicken embryo retinas and/or lenses with constructs expressing noggin, a secreted protein that binds BMPs and prevents their interactions with their receptors, delayed lens fiber cell elongation and increased cell death in the lens epithelium. In an in vitro explant system, in which chicken embryo or adult bovine vitreous humor stimulates chicken embryo lens epithelial cells to elongate into fiber-like cells, these effects were inhibited by noggin-containing conditioned medium, or by recombinant noggin. BMP2, 4, or 7 were able to reverse the inhibition caused by noggin. Lens cell elongation in epithelial explants was stimulated by treatment with FGF1 or FGF2, alone or in combination with BMP2, but not to the same extent as vitreous humor. These data indicate that BMPs participate in the differentiation of lens fiber cells, along with at least one additional, and still unknown factor.     

Insulin-like growth factors, IGF-1, IGF-2 and somatomedin C trigger cell proliferation in mammalian epithelial cells cultured in a serum-free medium

A single insulin-like growth factor which constitutes part of a defined serum-free medium is sufficient to stimulate DNA synthesis and mitosis in mammalian lens epithelial cells. Rabbit lenses were cultured in KEI-4, a medium which mimics rabbit aqueous humor, or in KEI-4 containing insulin growth factor I (IGF I), insulin growth factor II (IGF II) or somatomedin C. The magnitude of DNA synthesis and mitosis was evaluated on whole mount preparations of the epithelium at various times of culture. IGF I and II, the most highly purified of the insulin-like growth factors, and somatomedin C were equipotent lens mitogens, were active at the ng level, were more mitogenic toward lens epithelial cells than insulin, and initiated cell proliferation throughout the normally amitotic central region of the lens epithelium. The time course of the mitotic response elicited by the insulin-like growth factors was identical to that noted in lenses cultured in medium supplemented with serum or insulin. The present results, coupled with those of other investigators, suggest that insulin-like factors may regulate cell division in the mammalian lens in vivo.     

Lens epithelial cell apoptosis appears to be a common cellular basis for non-congenital cataract development in humans and animals

Cataract is a major ocular disease that causes blindness in many developing countries of the world. It is well established that various factors such as oxidative stress, UV, and other toxic agents can induce both in vivo and in vitro cataract formation. However, a common cellular basis for this induction has not been previously recognized. The present study of lens epithelial cell viability suggests such a general mechanism. When lens epithelial cells from a group of 20 cataract patients 12 to 94 years old were analyzed by terminal deoxynucleotidyl transferase (TdT) labeling and DNA fragmentation assays, it was found that all of these patients had apoptotic epithelial cells ranging from 4.4 to 41.8%. By contrast, in eight normal human lenses of comparable age, very few apoptotic epithelial cells were observed. We suggest that cataract patients may have deficient defense systems against factors such as oxidative stress and UV at the onset of the disease. Such stress can trigger lens epithelial cell apoptosis that then may initiate cataract development. To test this hypothesis, it is also demonstrated here that hydrogen peroxide at concentrations previously found in some cataract patients induces both lens epithelial cell apoptosis and cortical opacity. Moreover, the temporal and spatial distribution of induced apoptotic lens epithelial cells precedes development of lens opacification. These results suggest that lens epithelial cell apoptosis may be a common cellular basis for initiation of noncongenital cataract formation.     

Minireview: Apoptosis as seen through a lens

The lens represents an ideal model system for studying many of the cellular and molecular events of differentiation. It is composed of two ectodermally-derived cell types: the lens epithelial cells and the lens fibre cells, which are derived from the lens epithelial cells by differentiation. Programmed removal of nuclei and other organelles from the lens fibre cells ensures that an optically clear structure is created, while the morphology of the degenerating nuclei is similar to that observed during apoptosis and is accompanied by DNA fragmentation. These observations suggest the existence of biochemical parallels between the process of lens fibre cell organelle loss and classical apoptosis. For example, proteins encoded by the bcl-2 and caspase gene families are expressed in developing lenses and nuclear degeneration in lens fibre cells can be inhibited in vivo by overexpression of bcl-2 and in vitro by incubation of differentiating lens epithelial cell cultures with caspase inhibitors. Thus, the developing lens may represent a particularly useful model system for researchers interested in apoptosis. In this review, the recent literature pertaining to lens fibre cell organelle loss and its relationship to apoptosis is reviewed and possible future research directions are suggested.     

Developmental aspects of galectin-3 expression in the lens

In order to investigate the temporal and spatial expression pattern of the lectin galectin-3 during lens development we performed immunohistochemical studies using monoclonal and polyclonal antibodies against galectin-3 on paraffin sections of human, mouse and rat eyes. Galectin-3 has been shown to be involved in various biological functions related to cell adhesion, proliferation, apoptosis and differentiation in other tissues. In the human lens, galectin-3 shows a selective expression pattern during lens development. It is present in all cells of the early lens vesicle and at later stages it is strongly expressed during the elongation phase in differentiating primary lens fibres. From about 7 weeks onwards the anterior lens epithelium fails to express galectin-3. Adult lenses, however, exhibit immunoreactivity in the anterior epithelial cells and in the early differentiating secondary fibres of the lens' outer cortex prior to the onset of degradation of the nuclei. In contrast to the observed expression pattern in prenatal human lenses, mouse and rat lenses exhibited immunoreactivity for galectin-3 during postnatal and adult stages only. At these stages, the expression pattern closely resembles that seen in the corresponding human lenses. The spatiotemporal pattern of galectin-3 distribution during lens development favours a role of this lectin in adhesion processes and in the regulation of programmed organelle elimination during lens cell differentiation.     

Involvement of interleukin 18 in cataract development in hereditary cataract UPL rats

Our previous studies have demonstrated that lens epithelial damage by excessive nitric oxide causes an elevation in lens opacification in UPL rats, and it has been reported that interferon-gamma production in lens epithelial cells is involved in cataract development. In this study, we investigated the involvement of interleukin (IL)-18, which leads to interferon-gamma, in UPL rat lenses. The opacification of UPL rat lenses starts at 39 days of age. The gene expression levels causing IL-18 activation (IL-18, IL-18 receptor and caspase-1) are increased at 32 days of age, and the expression of mature IL-18 protein in the UPL rat lenses also increases with ageing. On the other hand, the interferon-gamma levels in UPL rat lenses are increased, and the increase in interferon-gamma levels in UPL rat lenses reaches a maximum at 39 days of age. Mature IL-18 expression and interferon-gamma production are achieved prior to the onset of lens opacification. In conclusion, the expression levels of IL-18 in the lenses of UPL rats are increased with aging. In addition, interferon-gamma levels in the lenses of UPL rats are also increased. It is possible that interferon-gamma generated by the activated IL-18 may induce cataract development in UPL rats.     

Ultrastructure of traumatic cataractogenesis in the frog: a comparison with mouse and human lens.

Normal and needle-punctured lenses of Rana pipiens were examined with the electron microscope in order to characterize the sequence of ultrastructural changes that follow the injury over a 5-month period. Results were compared with those obtained previously in experimentally injured mouse and accidentally injured human lenses. The normal adult frog lens was found to have a morphology similar to that of mammalian lenses. As in the human, frog lens epithelial cells contained scattered microfilaments and were connected by desmosomes and gap junctions. They differed from mouse cells, which had been shown to lack desmosomes and to have microfilaments organized into dense bundles. These differences are postulated to be related to the degree of accommodative deformation of the lens displayed by these species. After injury, cellular debris and fibrin, accumulated in the wound, were phagocytized by extrinsic cells derived from the blood and ocular tissues. Leucocytes, pigmented cells and fibroblasts remained in the wound for eight weeks, along with epithelial cells which proliferated and migrated from the wound margins.Epithelial cells showed an increase in those organelles associated with protein synthesis and transport, and in microfilaments. In cataractous lenses, epithelial cells showed changes in matrix, and lens fibers became organized into smaller, denser compressed units. At five months, considerable healing had taken place, but localized opacities persisted in many frog lenses.