Lentoids in aggregates of embryonic neural retina cells

Cellular signaling and factors involved in Müller cell gliosis: neuroprotective and detrimental effects

Müller cells are active players in normal retinal function and in virtually all forms of retinal injury and disease. Reactive Müller cells protect the tissue from further damage and preserve tissue function by the release of antioxidants and neurotrophic factors, and may contribute to retinal regeneration by the generation of neural progenitor/stem cells. However, Müller cell gliosis can also contribute to neurodegeneration and impedes regenerative processes in the retinal tissue by the formation of glial scars. This article provides an overview of the neuroprotective and detrimental effects of Müller cell gliosis, with accounts on the cellular signal transduction mechanisms and factors which are implicated in Müller cell-mediated neuroprotection, immunomodulation, regulation of Müller cell proliferation, upregulation of intermediate filaments, glial scar formation, and the generation of neural progenitor/stem cells. A proper understanding of the signaling mechanisms implicated in gliotic alterations of Müller cells is essential for the development of efficient therapeutic strategies that increase the supportive/protective and decrease the destructive roles of gliosis.

Regenerative capacity of retinal cells and the maintenance of their differentiation

Mechanisms underlying cell type stability and the capacity of retinal cells for transdifferentiation are discussed. It is shown that cells of amphibian pigmented epithelium can be transformed into retina or lens cells depending on the inducing cell type: the influence of retina enables them to be transformed into retina, the influence of lens epithelium, to lens cells (lentoids or lenses). This led to an attempt to discover the molecular character of cell action by means of transfilter induction in early gastrula ectoderm of Xenopus laevis. The results show that the induced cell types correspond to the main inducing cell type, around which a range of neighbouring cell types is produced; this has been shown for five different cell types. The inducing factors involved seem to show qualitative differences. It is probable that they play a stabilizing role in the maintenance of the differentiated state of tissues, since temporary dissociation into cells leads eye tissues to transdifferentiate into other types. Such molecular factors can play a significant role in the maintenance of the type of differentiation and also in conversion into other cell types. These mechanisms of maintenance are not restricted to interactions between molecules and cells, since membranes on the surface of the retina and pigmented epithelium contribute to their shaping and consequently to the stability of the cell type.

Lentoid Bodies in the Avian Retina

In-vitro studies suggest that, in avian retina, lentoid bodies arise from Müller cells or developing neuroretina. This report describes lentoid bodies in adult avian retinas in association with retinal trauma or degeneration. Retinal lentoids were identified in four birds (three owls and one parrot) in the course of routine diagnostic histopathology. Sections were stained with periodic acid-Schiff for the purposes of descriptive histology, and immunolabelled for a Müller cell marker (glial fibrillary acidic protein; GFAP) and a lens-specific marker (crystallin alpha-A). Intraretinal lentoids of varying size were identified, the constituent cells resembling bladder cells similar to those seen in cataracts. The process of lentoid formation followed a consistent pattern, characterized by progressive Müller cell hypertrophy in damaged areas, culminating in lentoid formation. GFAP immunoreactivity was strongest in Müller cells in the early stages of hypertrophy and receded as Müller cell hypertrophy advanced and lentoids developed. In contrast to GFAP immunoreactivity, crystalline alpha-A labelling increased in distribution and intensity as Müller hypertrophy became more prominent and lentoids were formed. This represents the first report of intraretinal lentoids in birds in vivo. The immunohistochemical data suggest that they arise from Müller cells. Association of lentoids with retinal damage supports the assertion that they arise following disruption of normal cell-cell communication.

The cellular and molecular bases of vertebrate lens regeneration

Lens regeneration takes place in some vertebrates through processes of cellular dedifferentiation and transdifferentiation, processes by which certain differentiated cell types can give rise to others. This review describes the principal forms of lens regeneration that occur in vivo as well as related in vitro systems of transdifferentiation. Classic experimental studies are reviewed that define the tissue interactions that trigger these events in vivo. Recent molecular analyses have begun to identify the genes associated with these processes. These latter studies generally reveal tremendous similarities between embryonic lens development and lens regeneration. Different models are proposed to describe basic molecular pathways that define the processes of lens regeneration and transdifferentiation. Finally, studies are discussed suggesting that fibroblast growth factors play key roles in supporting the process of lens regeneration. Retinoids, such as retinoic acid, may also play important roles in this process.

Difference between dorsal and ventral iris in lens producing potency in normal lens regeneration is maintained after dissociation and reaggregation of cells from the adult newt, Cynops pyrrhogaster

In Wolffian lens regeneration, lentectomized newt eye can produce a new lens from the dorsal marginal iris, but the ventral iris has never shown such capabilities. To investigate the difference of lens regenerating potency between dorsal and ventral iris epithelium at the cellular level, a transplantation system using cell reaggregates was developed. Two methods were devised for preparing the reaggregates from pigmented iris epithelial cells. One was rotating cells in an agar-coated multiplate on a gyratory shaker and the other was incubating cells in a microcentrifuge tube after slight centrifugation. Reaggregates made of dorsal iris cells that had been completely dissociated into single cells were phenotypically transformed into a lens when placed in the pupillary region of the lentectomized host eye. None of the ventral reaggregates produced a lens. Even dorsal reaggregates could not transdifferentiate into lens when they were placed away from the pupil. The produced lenses from the reaggregates were morphologically and immunohistochemically identified. To obtain evidence whether produced lenses really originated from singly dissociated cells, we labeled dissociated cells with a fluorescent dye (PKH26) before reaggregate formation and then traced it in the produced lens.

Presence of light-responding neurons in the reaggregate cultures of rat retinae

Since histological studies on retinal reaggregates have given evidence of lamination similar to that in the intact retina, the presence of retinal function, i.e. light response, in vitro has been expected as well. Therefore, neurons in the outermost layers of reaggregates, mostly consisting of amacrine cells, were studied with cell-attached recording. About one fifth of the neurons in that layer showed spontaneous discharges. Interestingly, the frequency of spontaneous discharges of some neurons increased with light stimulation but decreased to the basal level under dark conditions. They were reproducible and lasted more than 10 min in the best case. These results suggest that functional connections between photoreceptors which are exclusively present in the central region and amacrine cells in the outermost layer might be reconstituted in reaggregate cultures.

Regeneration of a chimeric retina from single cells in vitro: cell-lineage-dependent formation of radial cell columns by segregated chick and quail cells

We report here that similar to E6-chicken retinal cells, dissociated cells from 5.5-day-old (E5.5) quail retinae reaggregate in rotary culture, multiply about tenfold and reestablish histotypical areas. These cellular aggregates include all nuclear layers either with inversed or correct laminar polarity, depending on the local origin of the cells (called "rosetted" and "laminar" in-vitro-retinae (IVR), respectively; Layer and Willbold 1989). In combined cultures, chick and quail cells are evenly mixed only during the first two days of culture. Along with the assembly of single cells into rosettes and then into discrete laminae, sectors of chick and quail cells begin to segregate. They are delineated by borders running radially through all three nuclear layers. Thus, interspecies migration of cells at this advanced stage of differentiation is strongly inhibited. Concomitant with this segregation, coherent radial columns spanning all three layers but containing cells from either species only, can be traced histologically. We conclude that a weak segregation of chick and quail retinal cells takes place already at the single cell level, but that the permanent segregation of entire tissue parts must be due to clonal cellular proliferation within the IVR in conjunction with some developmental-structure mechanism retaining clonal progenies within a columnar order.

Lentoid formation in ectopic grafts of lentectomized eyes of rat foetuses

Enucleated and lentectomized eyeballs of 14- and 18-day rat foetuses were grafted under the kidney capsule of adult syngeneic rats for a period of 5-66 days. The grafts were then analysed by routine histology for the presence of lentoids. These developed only in 4 out of 41 grafts from the 18-day foetuses. Their origin from the retinal epithelium was evident from the cellular continuity via gradual transitional cellular forms. Lentoids did not develop in grafts from 14-day rat foetuses.

An immunocytochemical comparison of Müller cells and astrocytes in the cat retina

Immunocytochemical localization, at the light and electron microscopic levels, of five different known glial proteins was used to compare Müller cells with astrocytes in the adult cat retina. Retina from two different areas of the eye was examined. A region of retina on the border of the optic nerve was used because of its large population of astrocytes, and a region away from the optic nerve was used to examine Müller cells (astrocytes are sparse in this region). Antibodies to cellular retinaldehyde binding protein and glutamine synthetase labeled the Müller cells but not the astrocytes, while labeling with anti-carbonic anhydrase C, anti-alpha crystallin and anti-glial fibrillary acidic protein was found in both Müller cells and astrocytes.

Cellular and molecular background of wolffian lens regeneration

Based on studies of wolffian lens regeneration in the newt, in which the lens can be regenerated from the iris pigmented epithelium, we have shown by cell culture studies that the capacity of lens transdifferentiation is not limited to the newt cells, but widely conserved in pigmented epithelial cells (PECs) of chick and quail embryos and even of human fetuses. Recently, we have established a unique in vitro model system of chick embryonic PECs. In this culture system we are able to control each step of transdifferentiation from PECs into lens cells by regulating culture conditions and to produce a homogeneous cell population with potential for synchronous differentiation into either lens or pigment cell phenotype. These multipotent (at least bipotent) cells showed cellular characteristics resembling neoplastic cells in many ways. They did not express both lens and pigment cell specific genes analyzed so far, except delta-crystallin gene, which is expressed in developing lens of chick embryos. It has been proved by application of cell culture procedures of the system that PECs dissociated from fully-grown human eyes readily transdifferentiated into lens phenotypes in the manner observed in chick embryo PECs. In addition, we could predict that molecules detected in either cell surface or intercellular space stabilized the differentiated state of PECs in the newt and that the loss of these molecules might be one of the key steps of lens regeneration from the iris epithelium.

Immunohistochemical characterization of delta crystallin-containing retina/optic nerve "boundary" cells in the chick embryo

The term "transdifferentiation" has been used to describe the apparent phenotypic conversion of chick embryo neural retina Müller glial cells into lens-like cells in vitro. This phenotypic conversion is characterized by expression of such lens-specific proteins as delta crystallin and has been viewed as an example of cells transforming from the phenotype of a given tissue to that of another. We have identified a population of neuroglia-like cells in the embryonic chick retina which express high levels of delta crystallin as a function of normal development. The position and morphology of these cells is quite distinctive in that they form a loose meshwork which defines the boundary between the neural retina and the optic nerve head. These "boundary" cells are detectable as early as Day 5 of development through hatching. However, the meshwork structure formed by the cells is only readily observed between Days 8 and 9 of development. Double-immunolabeling procedures comparing delta crystallin staining to that of glial and neuronal markers suggest that these cells are a form of retinal Müller glial cell. The results show that under appropriate microenvironmental conditions, expression of delta crystallin falls into the normal repertoire of retinoblast cells. The results also demonstrate the presence of a cellular boundary defining the junction between the neural retina and the optic nerve, tissues that are ontogenetically and structurally continuous but functionally distinct.

An attempt to assay the state of determination by using transfected genes as probes in transdifferentiation of neural retina into lens

Hybrid genes coding for chloramphenicol acetyltransferase (CAT) with a non-specific retroviral, lens-specific delta-crystallin or lens-specific alpha-crystallin promoters were constructed to transfect the transdifferentiating (lentoidogenic) and non-transdifferentiating (non-lentoidogenic) cultures of chicken embryonic neural retina for assaying the state of determination towards lens differentiation. The expression occurred only when CAT genes with lens-specific promoters were transfected to the cultures maintained in the conditions permissive to lentoidogenesis. The expression of these exogenous, lens-specific CAT genes began at stages of culturing that were earlier than the expression of endogenous crystallin. Presumably, there are two steps in the transdifferentiation of neural retina into lens; acquisition of capacity to express crystallin genes and derepression of the endogenous crystallin genes.

Selective localization of glycine-accumulating cells in reaggregate culture of rat retina

Uptake of [3H]glycine into the cells either in monolayer or reaggregate cultures of retina from two-day-old rat pups was studied. The glycine-accumulating cells (glycine cells) had short processes with several branches. Only 5% of process-bearing cells were labelled in the monolayer cultures. The major cell type, previously identified as photoreceptor cells, was unlabelled. In reaggregate cultures, the glycine cells were localized mainly in the outermost layer of the reaggregate. But the proportion of positive cells among all the cells in that layer was not so large. Although the cell type of the glycine cells has not yet been unambiguously identified, these results demonstrate a possible example of selective sorting out of a group of biochemically distinct cells from a cell mixture.

Retinoic acid inhibits conversion of dissociated Müller glia into lens-like cells

In monolayer cultures of dissociated retina cells, Müller gliocytes undergo conversion into a lens-like cell type (lentoidal cells): they become unable to adhere to neurons and accumulate lens antigens. Retinoic acid (RA) retards these changes. We present evidence that RA prevents the rapid loss of gliocyte adhesivity to neurons; and that, by promoting restoration of glia cell contacts with neurons, RA protects the gliocytes from phenotype alteration.

A vital staining method for measuring the efficiency of transfection of eucaryotic cells

The xylE gene encodes catechol 2,3-dioxygenase, which catalyzes the conversion of catechol to 2-hydroxymuconic semialdehyde. The expression of this gene in eucaryotic cells can be detected simply by addition of catechol to the growth medium of the cells: cells that have a sufficient level of expression of the xylE gene stain yellow because of the accumulation of 2-hydroxymuconic semialdehyde. The number of stained cells is thus dependent upon the transfection efficiency as well as the level of expression of the xylE gene and is a measure of the combined transfection/expression efficiency in a particular cell type. Since the staining procedure does not affect the viability of the culture, the cells can be harvested afterward and analyzed for the expression of other, cotransfected, genes. This system for measuring transfection efficiency is especially useful when only small amounts of tissue are available.

In vitro analysis of cellular metaplasia from pigmented epithelial cells to lens phenotypes: a unique model system for studying cellular and molecular mechanisms of "transdifferentiation"

Pigmented epithelial cells (PECs) were dissociated from eyes of 8- to 9-day-old chick embryos and were cultured in EdF medium (Eagle's MEM supplemented with dialyzed fetal bovine serum) containing phenylthiourea (PTU) and testicular hyaluronidase (HUase). The PECs rapidly lost melanosomes as they proliferated and dedifferentiated in culture. These dedifferentiated PECs (dePECs) which did not manifest any identifiable specificity could be directed to one of two different differentiated phenotypes; viz., lens or pigment cells, depending upon subsequent culture conditions. Almost all dePECs began to synthesize melanin and redifferentiated to PECs by Day 10 of culture with EdF medium containing ascorbic acid (AsA). In contrast, the sister population of dePECs, when cultured at extremely high cell density with EdF medium containing PTU, HUase and AsA, synthesized delta-crystallin which is specific for lens. This transdifferentiation into lens cells occurred by Day 15 of culture. Using this culture system we are able to produce a homogeneous cell population with the potential for synchronous differentiation into either lens or pigment cell phenotype. The system is useful for studying mechanisms involved in cellular metaplasia.

Enhancement of expression of lens phenotype in cultures of pigmented epithelial cells by hyaluronidase in the presence of phenylthiourea

Pigmented epithelial cells isolated from 8-9-day-old chick embryos can transdifferentiate into lens-like cells at the terminal period of the third generation of culture. However, efficiency of this transdifferentiation is usually rather low. Phenylthiourea, a potent inhibitor of melanin synthesis, effectively enhances transdifferentiation of pigmented epithelial cells into lens-like cells in vitro. Lentoid bodies began to appear in the multilayered region of primary cultures of pigmented epithelial cells maintained in medium containing phenylthiourea at concentrations between 0.5 and 1.0 mM. Furthermore, the enhancing effect of phenylthiourea can be amplified with testicular hyaluronidase. Under these conditions, pigmented epithelial cells grow vigorously and lose their differentiative properties, efficiently switching their phenotype into lens-like cells some 20 days after initiation of culture in the presence of both substances. Semiquantitative analysis revealed that testicular hyaluronidase amplified the effect of phenylthiourea more than 100-fold. It has been suggested that phenotypic expression of pigmented epithelial cells during transdifferentiation can be regulated by manipulating the microenvironment in which these cells reside.

Formation of lentoids from retina gliocytes: ultrastructural study

In primary monolayer cultures of dispersed neural retina cells from 13-day chick embryo, gliocytes (Müller glia cells) multiply and rapidly change into a lentoidal (lens-like) phenotype. They express lens proteins, including MP26 (a lens plasma-membrane antigen) and ultra-structurally appear to resemble lens cells. A significant aspect of this modification is that the glia-derived lentoidal cells no longer display contact-affinity for neurons but become preferentially adhesive to each other; in aggregates, they assemble into compact lentoids. A likely explanation for this change in cell affinities is that the modified gliocytes express little or no R-cognin, a retinal cell-surface antigen implicated in mutual recognition and adhesion of retina cells. Although lentoidal cells express MP26, a gap-junction component in the lens, no gap junctions could be found in the lentoids.

Antiserum to lens antigens immunostains Müller glia cells in the neural retina

Antiserum to a lens fraction enriched for alpha-crystallin selectively immunostains Müller glia cells in the neural retina of several vertebrate species. Also, in embryonic retina (chicken), this antiserum reacts with Müller cells and, at early stages of development, with their apparent precursors. Thus, antibodies to a lens product(s) detect a Müller glia cell marker that begins to be expressed very early in their ontogeny and can be useful in studies on differentiation, function, and pathologies of this cell type.

Transformation of retinal glia cells into lens phenotype: expression of MP26, a lens plasma membrane antigen

We describe experiments in which dissociated cells from differentiated, post-mitotic neural retina of late chicken embryos (13 and 16 days) rapidly and consistently transform (transdifferentiate) in vitro into lens-like phenotype and form spherical lentoids. Using immunohistochemical and other tests, we have established that the lentoids arise from the progeny of definitive retinal glia cells (Müller cells). An early event in their transformation is the appearance in the cell surface of MP26, a plasma membrane protein characteristic of lens but not found in the retina. The results support the hypothesis that the phenotype of definitive glia cells in the retina is stabilized by contact-mediated interactions with neurons; disruption of cell contacts and cell separation alter surface properties of the glia cells, decontrol their phenotype, and predispose them to phenotype transformation.

Recent progress in studies of the transdifferentiation of eye tissue in vitro

A major switch in the overt differentiation phenotypes, which we call transdifferentiation, occurs very often in cultures of embryonic eye tissues. The systems provide irrevocable evidence for instability in the results of cell differentiation, and hence, studies on this topic are expected to contribute much to the understanding of the basic mechanisms of cell differentiation. In this article, recent work on transdifferentiation, mostly with chick embryos, was reviewed. Several new systems of lens transdifferentiation starting from brains, adenohypophyses, and other tissues have recently been discovered. Regarding the widely known cases of transdifferentiation starting from neural and pigmented retina cells, there has been considerable progress in elucidating the factors controlling such major switches in differentiation. In particular, efforts are under way to attempt to understand the mechanisms of transdifferentiation in relation to the transcriptional control of genes coding lens-specific proteins.

Three-dimensional hair follicular differentiation of a trichilemmoma cell line in vitro

A cell line was established in vitro from a benign hair follicular tumor of human trichilemmoma. Individual and organized cellular differentiation of this cell line was studied. When these cells were cultured for a long time (more than 3 weeks) without subculture, they started to pile up spontaneously. A part of the pile became indented and simultaneously the opposite side of the indentation budded out. The bud slowly elongated 2 to 3 mm in length in 8 to 12 weeks in culture. Light and electron microscopy revealed the internal structure of piles and elongated buds to be a three-dimensional hair follicular structure. The cells in the outermost layer were least mature. These were cuboid in shape and contained glycogen. The cells in the middle layer were more differentiated with a decreased amount of glycogen and an increased number of tonofilaments and desmosomes. The cells in the innermost layer were most differentiated. Cells were flat in shape and highly convoluted. The cell membrane was thickened as observed in cornified cells in vivo. These organized differentiations were also confirmed by histochemical and immunocytochemical studies; using a fluorescent thiol reagent, N-(7-dimethylamino-4-methylcoumarinyl)-maleimide method, free sulfhydryl groups were detected but disulfide bonds were absent in the early cell culture. Disulfide bonds increased slowly and accumulated in the innermost layer of piles. Accumulation of keratin substances, detected by indirect immunofluorescence method using anti-human keratin antibody, was also observed specifically in the piles. These results suggest that an established cell line of human trichilemmoma spontaneously produced, without stromal influence, hair follicular structures as well as individual cell differentiations in vitro as do trichilemmal (hair follicular) cells in vivo.

The accumulation of delta-crystallin mRNA in transdetermination and transdifferentiation of neural retina cells into lens

By means of hybridization with DNA complementary to delta-crystallin mRNA (delta-mRNA) sequences (delta-cDNA), the levels of delta-mRNA in three different culture systems of 8-day-old chick embryonic neural retina were determined. After 30 days of culturing in vitro, the level of delta-mRNA in cells cultured under conditions of spreading cultures (SpC) was 50 times higher than in the cells maintained in aggregate cultures (AgC) throughout. When the cells pre-cultivated in SpC for an initial 10 days were transferred into AgC, the delta-mRNA level in 30-day cultures was 40 times higher than that in 3-day SpC. The level of delta-mRNA in neural retina in situ was negligible, but it became detectable in 10-day SpC. The initial appearance of detectable delta-mRNA in 10-day SpC coincides with the timing of 'transdetermination' of neural retina cells into lens cells.

Commitment to transdifferentiation into lens occurs in neural retina cells after brief spreading culture of the dissociated cells

Cells dissociated from neural retina (NR) of 8-day-old chick embryos transdifferentiated into lens and pigment cells under conditions of stationary culture (spreading culture, SpC), whereas such an alteration in the pathways of differentiation did not occur under conditions of aggregate culture (AgC) with constant gyration for 28 days. When NR cells precultivated for longer than 10 days in SpC were transferred to AgC, extensive transdifferentiation into lens (and pigment cells) occurred in aggregates after a total of 28 days' cultivation in vitro. This was confirmed by immunofluorescent observations of histological sections of aggregates as well as by quantitative immunoelectrophoresis using specific antiserum against delta-crystallin. In 10-day SpC, the presence of delta-crystallin was not detected by immunological assay. Our results suggest that NR cells become committed or 'transdetermined' into lens direction before detectable expression of the lens phenotype, when cultured in SpC for 10 days.

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.