Glucosaminidase and Dedifferentiation of Newt Iris Epithelium

To try to understand the mechanism of the dedifferentiation process which occurs during metaplastic transformation of iris epithelial cells into lens cells in newt lens regeneration, the activity of N -acetylglucosaminidase in iris and iris epithelium was studied as a function of time after lentectomy. The activity was found to increase during the dedifferentiation phase of the iris epithelium. The dorsal iris, where definite dedifferentiation occurs side by side with incomplete dedifferentiation, shows significantly greater enhancement of the activity than the ventral iris, where only incomplete dedifferentiation takes place. When the cells complete dedifferentiation and engage in redifferentiation into lens cells, the level of activity drops, approaching that of the normal lens. Evidence is also presented for release of the enzyme into the ocular fluid during dedifferentiation. The possibility that the enzyme is involved in surface alterations of iris epithelial ceils engaged in dedifferentiation is discussed.     

Pathways of differentiation in chick embryo neuroretinal cultures

Markers of neuronal cell differentiation (GABA accumulation, choline acetyltransferase activity) are shown to increase initially and then decline sharply in monolayer cultures of 9 day embryo neuroretinal (NR) cells. A glial marker (glutamine synthetase, GSase) is precociously inducible by hydrocortisone (HC) in dens "monolayer' NR cultures (containing aggregates of neuronal cells overlying the glian sheet) as well as in chick embryo retinal explants. The induced level of GSase activity is not maintained in the continued presence of HC, but rather declines by 20 days in vitro. Choline acetyltransferase (CAT) activity is higher in HC-treated cultures than in controls only during the period when induced GSase activity is detectable. Furthermore, the subsequent transdifferentiation of lens cells (monitored as delta crystalline content) in these cultures is delayed by 10 days and much reduced in extent when HC is present throughout the culture period. We suggest a simple model to account for these results, on the basis of recent evidence that lens cells are derived mainly from the retinal epithelial cells (immature Müller glia) of 9-day embryonic NR, and that transdifferentiation results from a change in cell determination during the early stages of "monolayers' culture. In outline, our model proposes that early determination of the retinal glia is associated with a decline of neuronal cell markers (dedifferentiation) followed eventually by loss of the neuronal cells. Hydrocortisone, by inducing transient glial cell differentiation (GSase activity), both prolongs the expression of a neuronal marker (CAT) and also reduces later transdifferentiation into lens.     

Pathways of Differentiation in Chick Embryo Neuroretinal Cultures

Markers of neuronal cell differentiation (GABA accumulation, choline acetyltransferase activity) are shown to increase initially and then decline sharply in monolayer cultures of 9 day embryo neuroretinal (NR) cells. A glial marker (glutamine synthetase, GSase) is precociously inducible by hydrocortisone (HC) in dense'monolayer' NR cultures (containing aggregates of neuronal cells overlying the glial sheet) as well as in chick embryo retinal explants. The induced level of GSase activity is not maintained in the continued presence of HC, but rather declines by 20 days in vitro. Choline acetyltransferase (CAT) activity is higher in HC-treated cultures than in controls only during the period when induced GSase activity is detectable. Furthermore, the subsequent transdifferentiation of lens cells (monitored as δ crystallin content) in these cultures is delayed by 10 days and much reduced in extent when HC is present throughout the culture period.
We suggest a simple model to account for these results, on the basis of recent evidence that lens cells are derived mainly from the retinal epithelial cells (immature Müller glia) of 9-day embryonic NR, and that transdifferentiation results from a change in cell determination during the early stages of'monolayer' culture. In outline, our model proposes that early dedetermination of the retinal glia is associated with a decline of neuronal cell markers (dedifferentiation) followed eventually by loss of the neuronal cells. Hydrocortisone, by inducing transient glial cell differentiation (GSase activity), both prolongs the expression of a neuronal marker (CAT) and also reduces later transdifferentiation into lens.     

Apoptosis in lens development and pathology

The ocular lens is a distinct system to study cell death for the following reasons. First, during animal development, the ocular lens is crafted into its unique shape. The crafting processes include cell proliferation, cell migration, and apoptosis. Moreover, the lens epithelial cells differentiate into lens fiber cells through a process, which utilizes the same regulators as those in apoptosis at multiple signaling steps. In addition, introduction of exogenous wild-type or mutant genes or knock-out of the endogenous genes leads to apoptosis of the lens epithelial cells followed by absence of the ocular lens or formation of abnormal lens. Finally, both in vitro and in vivo studies have shown that treatment of adult lens with stress factors induces apoptosis of lens epithelial cells, which is followed by cataractogenesis. The present review summarizes the current knowledge on apoptosis in the ocular lens with emphasis on its role in lens development and pathology.     

Induction of heme oxygenase-1 modulates cis-aconitase activity in lens epithelial cells

Heme oxygenase-1 is the heme catabolic enzyme induced in human dermal fibroblasts by environmental stress. We report an increase of heme oxygenase-1 message in lens epithelial cells after exposure to UVA radiation, followed by a 10-fold increase of protein expression. The size of message was larger than previously demonstrated for fibroblasts. The relationship between heme oxygenase-1 activation and iron metabolism was investigated by measurement of activities of both cytosolic and mitochondrial cis-aconitase enzymes. A 2-fold increase in mitochondrial cis-aconitase activity in UVA-exposed cells coincided with the time of maximal heme oxygenase-1 expression. We propose that modulation of cis-aconitase activity at the translational level by an increase of cellular iron is an important consequence of heme oxygenase-1 activation. This might be a novel aspect of the protective role of heme oxygenase-1 in modulating the response of cells challenged with oxidative stress.     

Effects of naphthalene metabolites on cultured cells from eye lens

Naphthalene is toxic to the eye and results in opacification of the lens. To investigate the metabolic events that may be occurring in the lens epithelial cells, a cell line of lens from a transgenic mouse was incubated with various metabolites of naphthalene. Naphthoquinone at 50 microM was toxic to most cells with a depletion of glutathione levels noted within 6 h of incubation. At 10 microM, naphthoquinone caused an increase in specific activity of the enzyme DT-diaphorase. This enzyme is thought to be a defense against quinones since semiquinone formation is thought to be lessened. Naphthalene-1,2-dihydrodiol at 50 microM also caused an increase in the specific activity of the DT-diaphorase, while at 10 microM no apparent change occurred in the cells. Although there was evidence of metabolic alterations in the cells with the metabolites of naphthalene, the protein profile by two-dimensional gel electrophoresis did not change and there was no indication of an increase in carbonyl formation in the soluble proteins of the cells. These experiments indicate that the metabolites of naphthalene can cause alteration in the metabolism of the lens cells but may not cause apparent changes in the major proteins within the lens epithelium.     

The control of δ-crystallin gene expression during lens cell development: Dissociation of cell elongation,cell division, δ-crystallin synthesis,and δ-crystallin mRNA accumulation

Previous studies have shown that freshly explanted 6-day-old embryonic chick lens epithelial cells elongate, differentially increase their synthesis of δ-crystallin, and accumulate δ-crystallin mRNA when cultured with fetal calf serum; in contrast, precultured serum-starved 6-day-old and freshly explanted 19-day-old embryonic epithelial cells divide when treated with fetal calf serum. We have explored whether the stimulation of δ-crystallin gene expression (as measured by δ-crystallin synthesis and δ-crystallin mRNA accumulation) is affected by inhibiting lens cell elongation with colchicine, and whether δ-crystallin gene expression is increased in lens epithelial cells stimulated to divide by treatment with fetal calf serum, as it is in those stimulated to elongate by treatment with serum. Three new findings were made in this study. First, the stimulation of δ-crystallin gene expression does not require elongation of the cultured lens cells. Second, a decreased proportion of δ-crystallin synthesis is observed in lens epithelial cells during normal development and during serum starvation; in neither case is this decrease associated with a reduction in the number of δ-crystallin mRNA sequences per cell. Finally, serum stimulation of lens cell division does not increase the proportion of δ-crystallin synthesis, but can promote the accumulation of δ-crystallin mRNA. Thus, the relative proportion of δ-crystallin synthesized during chick lens development is not solely a function of the number of δ-crystallin mRNA sequences in the lens cells.     

The mechanism of cell elongation during lens fiber cell differentiation

Lens fiber formation is characterized by extensive cell elongation. Earlier studies have shown that lens cell elongation in vitro can occur in the absence of microtubules and is associated with a proportional increase in cell volume. We have previously suggested that lens fiber cell elongation is directly caused by an increase in cell volume. In this report, lenses from 3- and 6-day-old chicken embryos were three-dimensionally reconstructed from serial sections to provide a measure of cell volume and length during various stages of primary and secondary lens fiber formation. In both cases, cell volume was highly correlated with cell length during lens cell elongation. In addition, during primary lens fiber formation, large intercellular spaces between lens vesicle cells disappeared as these cells began to elongate to form lens fibers. Loss of intercellular spaces would be expected if increasing cell volume were responsible for cell elongation. Finally, results of experiments in which the lens capsule was cut with a fine tungsten needle suggested that the capsule was elastic and normally under tension. These findings were used to formulate a model which accounts for the major events in lens morphogenesis based on (1) the regulation of cell volume, (2) the junctions present between lens cells, and (3) the constraint provided by the elasticity of the lens capsule.     

pp60c-src expression in transdifferentiating cultures of embryonic chick neural retina cells

Chick embryo neural retinal cells transdifferentiate extensively into lens cells when cultured in Eagle's MEM containing horse and fetal calf sera (FHMEM). Such cultures express elevated levels of pp60c-src-associated tyrosine kinase activity relative to parallel cultures prevented from transdifferentiating by the addition of supplementary glucose (FHGMEM) or replacement of MEM by medium 199 (F199). Northern blotting and in vitro translation studies suggest that c-src mRNA levels are only slightly higher in late transdifferentiating (FHMEM) cultures as compared to parallel blocked (FHGMEM or F199) cultures. By immunocytochemical staining, we show that pp60c-src protein is largely localized in cell groups undergoing conversion into lens (i.e. expressing delta crystallin) in late FHMEM cultures. Initial studies of pp60c-src in chick lens tissues during development indicate that higher kinase activity is found in the epithelial cells relative to mature lens fibres. Thus pp60c-src may be expressed both during the differentiation of lens cells in vivo and during the transdifferentiation of neural retina cells into lens in vitro.     

Phosphatidylcholine and phosphatidylethanolamine metabolism during lens fiber cell formation

Phosphatidylinositol is metabolized with a half-life of about 5 h in lens epithelial cells of 6-day-old embryonic chickens. When these cells differentiate to form lens fiber cells, however, phosphatidylinositol turnover virtually ceases. The present study was undertaken to determine whether there is a similar change in the metabolism of phosphatidylcholine and phosphatidylethanolamine. [32P]Orthophosphate was injected into 6-day-old chicken embryos, and the incorporation of label into phosphatidylcholine and phosphatidylethanolamine was followed for 48 h. The specific activities of the precursors phosphorylcholine and phosphorylethanolamine were also measured during this time. The data were then analysed by means of a simple kinetic model to determine the rate of synthesis and the half-life of each phospholipid. The results showed that phosphatidylcholine is synthesized at a rate of about 1.2 X 10(-20) mol/s per cell in the lens epithelial cells, and 6.4 X 10(-20) mol/s per cell in the fiber cells. Phosphatidylethanolamine is synthesized at approximately 0.9 X 10(-2)) mol/s per cell in the epithelial cells, and 4.0 X 10(-20) mol/s per cell in the fiber cells. Both phospholipids are stable in both the epithelial cells and in the fiber cells, with half-lives of 48 h or greater. Thus, although phosphatidylcholine, phosphatidylethanolamine and phosphatidylinositol all experience an increase in synthesis following lens fiber formation, the previously observed decrease in phosphatidylinositol turnover accompanying differentiation is a specific effect.     

DNA strand breakage during physiological apoptosis of the embryonic chick lens: Free 3' OH end single strand breaks do not accumulate even in the presence of a cation-independent deoxyribonuclease

Epithelial cells from the lens equator differentiate into elongated fiber cells. In the final steps of differentiation, the chromatin appears quite condensed and chromatin breakdown into nucleosmes occurs. DNA breaks due to an endodeoxyribonuclease activity corresponding to at least two polypeptides of 30 and 40 kDa have been identified. To identify the nature and the developmental appearance of initial breaks, nick translation reaction was followed both biochemically and in situ in fiber and epithelial cells from chick embryonic lenses. There is no accumulation of single-strand breaks (SSB) with 3'OH ends in lens fiber cells during embryonic development. Such damage can be increased in these cells by treatment with DNAase I indicating the absence of an inhibitor of the nick translation reaction in fiber cells. However, there are indications of the presence of DNA breaks with blocked termini when the phosphatase activity of nuclease P1 is used. The presence of breaks is also indicated by the large amounts of (ADP-ribose)_n found in lens fibers particularly at 11 days of embryonic development (E11) as ADP-ribosyl transferase binds to and is activated by DNA strand breaks. Incubation of lens cells in vitro, which causes nucleosomal fragmentation only in fiber cells, produces SSB with 3'OH ends in both epithelia and fibers. Incubation for short periods, observed in experiments in situ, induces SSB first in the central fiber nuclei, which are late in differentiation. This may indicate that these SSB play a physiological role. Long incubations produce larger numbers of SSB in epithelia than fibers. The SSB in the fibers may have been converted into double-strand breaks (D SB), seen as nucleosomal fragments, and therefore no longer act as substrates for nick translation. The nuclease activity responsible for SSB production is independent of divalent cations and could be implicated in lens terminal differentiation. © 1994 Wiley-Liss, Inc.     

Junctions between lens cells in differentiating cultures: structure, formation, intercellular permeability, and junctional protein expression

We previously described cultures of chick embryo lens cells which displayed a marked degree of differentiation. In this report, the junctions found between the lens fiber-like cells in the differentiated "lentoids" are characterized in several ways. Thin-section methods with electron microscopy first demonstrated that numerous, large junctions between lentoid cells accompanied the other differentiated features of these cells. Freeze-fracture techniques, including quantitative analysis, then revealed that (a) junctional particles were loosely arranged as is typical of fiber cells, (b) the population of individual junctional areas in culture was indistinguishable from that found in 10- to 12-day chick embryo lenses, and (c) apparent junction formation occurred during the development of the lens cells, with lacy arrays of particles being associated with fiber-like junctions. In addition, gap junctions with hexagonally packed particles, typical of lens epithelial cells, largely disappeared during the course of differentiation. Injection of tracer dyes into lentoid cells resulted in rapid intercellular movement of dye, consistent with functional cell-to-cell channels connecting lentoid cells. During the development of the lens cells in culture, as junction formation occurred, an increase of approximately eight-fold in MP28 protein was observed within the cells. These combined results indicate that (a) extensive lens fiber junctions and functional cell-to-cell channels are found between differentiated lentoid lentoid cells in vitro, (b) lens fiber junctions appear to form during the course of lens cell differentiation in culture, (c) a significant increase occurs in the putative junctional protein before the cultures are highly developed, (d) the increased levels of MP28 and junction formation may be required for the full expression of the differentiated state in the lens fiber cell, and (e) this culture system should prove to be valuable for additional experiments on lens junctions and for other studies requiring the development of lens fiber cells in vitro.     

Mechanism of repair of lenticular wounds in Rana pipiens. I. Role of cell migration

The earliest visible changes that occur in the normal organization of the lens epithelium after a penetrating wound in the lens suggest that passage of an injury stimulus outward from the wound occurs within the first half day after injury: changes in normal tissue architecture appear near the wound at six hours and move outward to involve the proliferative zone by 12 hours. This is followed by migration of cells toward the wound. There is a slight increase in cell number in the proliferative zone within the first day, followed at later intervals by a decrease there and a concomitant increase in cell number adjacent to the wound. After a pre-injury injection of H³-TdR (or I¹²⁵-UdR), labeled cells that had incorporated the precursor in the normal proliferative zone were found progressively closer to the wound with increasing time. Only the cells which incorporated the radioactive tracer could be followed, but it is likely that cells in the central areas also migrated toward the wound since they showed spindling and superimposition. Migration of cells into the wound margins is an important phase of wound closure which begins long before the major productions of new cells by mitosis.     

Decrease of DNA per cell during development of the lens in chickens.

Developmental changes in the amount and conformation of DNA in chicken lens were studied. For this, DNA in situ in lens fiber cell nuclei of chickens was examined by microfluorometry with Hoechst 33258 (Hoe) fluorochrome. On 1 M NaCl-aided Hoe staining, by which the amount of DNA can be determined accurately, the fluorescence intensity of lens fiber cells was found to decrease with no change in that of the lens epithelial cells during development. On the contrary, on normal NaCl-free Hoe staining the fluorescence intensity of the lens cells was found to increase gradually during development. These results suggest that during development the amount of DNA in lens fiber cells decreases in association with some change in its conformation.     

Decrease of DNA per cell during development of the lens in chickens

Summary Developmental changes in the amount and conformation of DNA in chicken lens were studied. For this, DNA in situ in lens fiber cell nuclei of chickens was examined by microfluorometry with Hoechst 33258 (Hoe) fluorochrome. On 1 M NaCl-aided Hoe staining, by which the amount of DNA can be determined accurately, the fluorescence intensity of lens fiber cells was found to decrease with no change in that of the lens epithelial cells during development. On the contrary, on normal NaCl-free Hoe staining the fluorescence intensity of the lens cells was found to increase gradually during development. These results suggest that during development the amount of DNA in lens fiber cells decreases in association with some change in its conformation.