Members of the bcl-2 and caspase families regulate nuclear degeneration during chick lens fibre differentiation.

The optical clarity of the lens is ensured by the programmed removal of nuclei and other organelles from the lens fibre cells during development. The morphology of the degenerating nuclei is similar to that observed during apoptosis and is accompanied by DNA fragmentation. Proteins encoded by the bcl-2 proto-oncogene family are important in either promoting or inhibiting apoptosis, and caspases are involved in downstream proteolytic events. Here, the expression of bcl-2 family members (bcl-2, bax, bad, and bcl-x(s/l)) and caspases-1, -2, -3, -4, and -6 was investigated through a range of stages of chick lens development using immunocytochemistry, Western blotting, and affinity labelling for caspases using biotinylated caspase inhibitors. Using differentiating lens epithelial cell cultures, it was demonstrated that the addition to cultures of synthetic peptide inhibitors of caspases -1, -2, -4, -6, and -9 brought about a 50-70% reduction in the number of degenerating nuclei per unit area of culture, as assessed by image analysis. These effects were comparable to those seen when general inhibitors of caspases were added to cultures. On the other hand, inhibitors of caspases-3 and -8 were not effective in significantly reducing the number of TUNEL-labelled nuclei. Expression of the caspase substrates poly(ADP-ribose) polymerase (PARP) and the 45-kDa subunit of DNA fragmentation factor (DFF 45) was also observed in the developing lens. Western blots of cultures to which caspase inhibitors were added revealed alterations in the PARP cleavage pattern, but not in that of DFF. These results demonstrate a role for members of the bcl-2 family and caspases in the degeneration of lens fibre cell nuclei during chick secondary lens fibre development and support the proposal that this process has many characteristics in common with apoptosis.     

Retroviral overexpression of bcl-2 in the embryonic chick lens influences denucleation in differentiating lens fiber cells

During the course of their differentiation, embryonic lens fibers undergo loss of their cytoplasmic organelles and nuclei. The denucleation process bears similarities to the nuclear breakdown that occurs during apoptosis. This has given rise to the hypothesis that this denucleation is analogous to apoptosis, but without the plasma membrane changes characteristic of apoptotic cell death. Previous work has shown that several members of the apoptotic cascade are active during denucleation. Here, we have overexpressed the anti-apoptotic molecule bcl-2 in developing lenses of the 8-day-old chick embryo in ovo, using the replication-competent retrovirus RCAS. We find that lenses overexpressing bcl-2 show varying degrees of distortion in comparison with untreated and negative insert controls, including a more spherical shape and disorganized fiber cells. All overexpressing lenses showed significantly higher numbers of smaller nuclei in the lens core, where denucleation begins. There was no change in cell size or pattern of proliferation. These in vivo results were confirmed in vitro using lens epithelial cell cultures, which differentiate into lentoids. The lentoids in treated cultures showed the same effect on nuclear number and size. We further found that in lenses overexpressing bcl-2 there was a reduction in the activation of caspase-9 and the cleavage of the caspase substrate DFF45, and, in the lens core, a failure of the nuclear chromatin to condense. These results provide strong support for the view that embryonic lens fiber cell denucleation is analogous to the nuclear degradation that occurs during apoptosis, and that similar control pathways are involved in both these phenomena.     

TGFβ1 induces growth arrest and apoptosis but not ciliated cell differentiation in rat tracheal epithelial cell cultures

Summary We are studying the regulation of ciliated cell differentiation using an in vitro model of tracheal regeneration. Previously, we reported that removal of growth stimulating compounds such as epidermal growth factor (EGF) and cholera toxin reduced DNA synthesis and cell number while increasing ciliated cell differentiation (Clark et al., 1995). This result suggested that the induction of growth arrest may stimulate terminal differentiation of airway epithelial cells into ciliated cells. Transforming growth factor βs (TGFβs) inhibit epithelial cell proliferation and have also been shown to stimulate epithelial cell differentiation. In this study, the effect of TGFβ₁ on growth and ciliated cell differentiation of rat tracheal epithelial (RTE) cells was examined. TGFβ₁ inhibited [³H]thymidine incorporation by RTE cells in a dose-dependent manner. A 40% inhibition was observed after a 24-h incubation with 10 pM TGFβ₁. Continuous treatment with TGFβ₁ (1–50 pM) also reduced cell number during the time when ciliogenesis occurs. This reduction resulted in part from a loss of cells through exfoliation, in addition to the inhibition of proliferation. The exfoliated cells exhibited several morphological features characteristic of apoptosis, including shrunken cells, condensed and fragmented nuclei, and intact organelles. In addition, electrophoretic analysis of genomic DNA analysis isolated from exfoliated cells demonstrated the presence of a nucleosomal ladder. However, in contrast to the removal of EGF, treatment with TGFβ₁ for 7 d did not increase ciliated cell differentiation. TGFβ1 is, therefore, capable of inhibiting proliferation and increasing apoptosis in RTE cells without stimulating ciliated cell differentiation.     

bFGF suppresses serum-deprivation-induced apoptosis in a human lens epithelial cell line.

There is increasing evidence that basic fibroblast growth factor (bFGF) plays an important role in cell proliferation, differentiation, and survival in various systems. In the eye, although a truncated, dominant negative bFGF receptor in transgenic mice induced defective lens development and caused lens fiber cells to display characteristics of apoptosis, there is little direct evidence of the effect of bFGF on lens epithelial cell apoptosis. Our study examines the effects of bFGF on programmed cell death induced by serum deprivation using a human lens epithelial cell line. Cells supplemented with 20% fetal bovine serum were used as normal controls. Over a period of 7 days, the addition of 100 ng/ml bFGF effectively suppressed serum-deprived apoptosis. The expression of gamma-crystallin and major intrinsic protein, which are markers of lens cell differentiation, was not detected. Also there was no significant difference in cell proliferation between serum-deprived cells with or without bFGF. ICE (caspase-1) was expressed under both the conditions, but the level of expression between the two groups was not substantially different. bcl-2 and c-myc were upregulated only in bFGF-treated cells. Thus we speculate that the inhibitory effect of bFGF on apoptosis is through the upregulation of the inhibitor of apoptosis, instead of downregulation of the initiator. This effect appears to be independent of lens cell differentiation and proliferation.     

Human bcl-2 gene attenuates the ability of rabbit lens epithelial cells against H2O2-induced apoptosis through down-regulation of the alpha B-crystallin gene

It is well established that the proto-oncogene, bcl-2, can prevent apoptosis induced by a variety of factors. Regarding the mechanism by which BCL-2 prevents cell death, one theory suggests that it acts by protecting cells from oxidative stress. In the lens system, oxidative stress-induced apoptosis is implicated in cataractogenesis. To explore the possibility of anti-apoptotic gene therapy development for cataract prevention and also to further test the anti-oxidative stress theory of BCL-2 action, we have introduced the human bcl-2 gene into an immortalized rabbit lens epithelial cell line, N/N1003A. The stable expression clones of both vector- and bcl-2-transfected cells have been established. Treatment of the two cell lines with H(2)O(2) revealed that bcl-2-transfected cells were less capable of detoxifying H(2)O(2) than the control cells. Moreover, bcl-2-transfected cells are more susceptible to H(2)O(2)-induced apoptosis. To explore why bcl-2-transfected cells have reduced resistance to H(2)O(2)-induced apoptosis, we examined the expression patterns of several relevant genes and found that expression of the alphaB-crystallin gene was distinctly down-regulated in bcl-2-transfected cells compared with that in vector-transfected cells. This down-regulation was specific because a substantial inhibition of BCL-2 expression through antisense bcl-2 RNA significantly restored the level of alphaB-crystallin and, moreover, enhanced the ability of the bcl-2-transfected cells against H(2)O(2)-induced apoptosis. Introduction of a mouse alphaB-crystallin gene into bcl-2-transfected cells also counteracted the BCL-2 effects. Down-regulation of alphaB-crystallin gene was largely derived from changed lens epithelial cell-derived growth factor activity. Besides, alphaB-crystallin prevents apoptosis through interaction with procaspase-3 and partially processed procaspase-3 to prevent caspase-3 activation. Together, our results reveal that BCL-2 can regulate gene expression in rabbit lens epithelial cells. Through down-regulation of the alphaB-crystallin gene, BCL-2 attenuates the ability of rabbit lens epithelial cells against H(2)O(2)-induced apoptosis.     

Lens fibre cell differentiation and organelle loss: many paths lead to clarity

The programmed removal of organelles from differentiating lens fibre cells contributes towards lens transparency through formation of an organelle-free zone (OFZ). Disruptions in OFZ formation are accompanied by the persistence of organelles in lens fibre cells and can contribute towards cataract. A great deal of work has gone into elucidating the nature of the mechanisms and signalling pathways involved. It is apparent that multiple, parallel and redundant pathways are involved in this process and that these pathways form interacting networks. Furthermore, it is possible that the pathways can functionally compensate for each other, for example in mouse knockout studies. This makes sense given the importance of lens clarity in an evolutionary context. Apoptosis signalling and proteolytic pathways have been implicated in both lens fibre cell differentiation and organelle loss, including the Bcl-2 and inhibitor of apoptosis families, tumour necrosis factors, p53 and its regulators (such as Mdm2) and proteolytic enzymes, including caspases, cathepsins, calpains and the ubiquitin-proteasome pathway. Ongoing approaches being used to dissect the molecular pathways involved, such as transgenics, lens-specific gene deletion and zebrafish mutants, are discussed here. Finally, some of the remaining unresolved issues and potential areas for future studies are highlighted.     

GROWTH OF THE CHICKEN EMBRYONIC LENS TRANSPLANTED ONTO THE CHORIO-ALLANTOIC MEMBRANE

The influence of neural retina on the growth of chicken embryonic lens was studied by comparing the growth pattern of the lens transplanted onto chorio-allantoic membrane (CAM) with that of the normal lens. The lens from 6-day embryo, transplanted onto CAM after labeled with ³H-thymidine, continued to grow in the absence of neural retina at least for 12 days of incubation, although its growth rate was reduced. In the transplanted lens, no ³H-labeled epithelial cell differentiated into fiber at least for 2 days of incubation and ³H-labeled nuclei first appeared in the fiber cells on the fourth day of incubation, while, in the normal lens of 6-day embryo labeled with ³H-thymidine in situ, ³H-labeled epithelial cells differentiated into fibers within 24 hours. On the other hand, the fiber cells differentiated before transplantation maintained the nearly normal growth rate on CAM. The neural retina transplanted onto CAM together with lens induced the new fibers from the lens epithelium. These observations suggest that the neural retina initiates and promotes the fiber differentiation in the chicken lens, but its continued influence is not always necessary for the successive differentiation of epithelial cell into fiber and especially for the growth of the differentiated fiber cells.     

bcl-2 overexpression inhibits cell death and promotes the morphogenesis, but not tumorigenesis of human mammary epithelial cells [published erratum appears in J Cell Biol 1995 Nov;131(4):following 1121]

Overexpression of the B cell leukemia/lymphoma-2 (bcl-2) gene has been shown to confer a survival advantage on cells by inhibiting apoptosis. In epithelia, the bcl-2 gene is also related to development and differentiation, and the protein is strongly expressed in the embryo in the epithelial cells of the developing mammary gland. To investigate directly the effect of bcl-2 on human epithelial cells, we used an amphotropic recombinant retrovirus to introduce the gene into nontumorigenic cell lines developed from luminal epithelial cells cultured from milk. Here we demonstrate that while bcl-2 overexpression does not directly induce the tumorigenic phenotype, it provides a survival advantage to the mammary epithelial cells by inhibiting cell death at confluence or under conditions of serum starvation, bcl-2 can also affect the phenotype of the original epithelial cells, and promote epithelial-mesenchymal conversion, accompanied by loss of the cell adhesion molecules E-cadherin and alpha 2 beta 1 integrin. The extent of the epithelial-mesenchymal conversion varies with small differences in the phenotype of the parental line and with the level of expression of Bcl-2 and in some cases cell lines emerge with a mixed phenotype. The increased survival of Bcl-2-expressing cells at confluence results in multilayering, and the development of three- dimensional structures. Where a mixed phenotype is observed these structures consist of an outer layer of polarized epithelial cells separated by a basement membrane-like layer from an inner mass of fibroblastoid cells. Branching morphogenesis of bcl-2 transfectants is also observed in collagen gels (in the absence of fibroblast growth factors). The results strongly indicate that by increasing their survival under restrictive growth conditions, and by modifying the epithelial phenotype, bcl-2 can influence the specific morphogenetic behavior of mammary epithelial cells.     

The canonical intrinsic mitochondrial death pathway has a non-apoptotic role in signaling lens cell differentiation

The mitochondrial cell death pathway is known for its role in signaling apoptosis. Here, we describe a novel function for the mitochondrial cell death pathway in signaling initiation of differentiation in the developing lens. Most remarkably, we induced lens cell differentiation by short-term exposure of lens epithelial cells to the apoptogen staurosporine. Activation of apoptosis-related pathways induced lens epithelial cells to express differentiation-specific markers and to undergo morphogenetic changes that led to formation of the lens-like structures known as lentoids. The fact that multiple stages of differentiation are expressed at a single stage of development in the embryonic lens made it possible to precisely determine the timing of expression of proteins associated with the apoptotic pathway. We discovered that there was high expression in the lens equatorial epithelium (the region of the lens in which differentiation is initiated) of pro-apoptotic molecules such as Bax and Bcl-x(S) and release of cytochrome c from mitochondria. Furthermore, we found significant caspase-3-like activity in the equatorial epithelium, yet this activity was far lower than that associated with lens cell apoptosis. These apoptotic pathways are likely regulated by the concurrent expression of prosurvival molecules, including Bcl-2 and Bcl-x(L); phosphorylation of Bad; and high expression of inhibitor of apoptosis proteins chicken IAP1, IAP3, and survivin. This finding suggests that prosurvival pathways allow pro-apoptotic molecules to function as molecular switches in the differentiation process without tipping the balance toward apoptosis. We call this process apoptosis-related Bcl-2- and caspase-dependent (ABC) differentiation.     

Chromatin condensation and terminal differentiation process in embryonic chicken lens in vivo and in vitro

During embryonic chick lens differentiation, the epithelial cells become transformed into elongated fibres. Concomitantly, the fibre nuclei undergo degeneration and high molecular weight (HMW) DNA breaks down due to nuclear endodeoxyribonuclease activity. An electronmicroscopic study of lens epithelial and fibre nuclei was made at different stages of chick embryonic development, both in vivo and in vitro. The in vitro conditions are conducive to the expression of endogenous endodeoxyribonuclease activity in fibres. In both conditions we observed condensation of chromatin. The organization of some nuclear material into distinct linear arrays followed by streaming of nuclear material into the cytoplasm is recorded only in vitro. Such a condition may lead to acceleration of the process of aging in lens fibres.     

Apoptosis Induced by Differentiation or Serum Deprivation in an Immortalized Central Nervous System Neuronal Cell Line

Abstract: To characterize the nature of programmed cell death (PCD) induced in neuronal cells during development, three regulators of apoptosis were investigated: one, the bcl-2-related genes, modulate cell survival, and the other two, the interleukin-1β converting enzyme (ICE)-related enzymes and the tumor suppressor protein p53, have been implicated as mediators of apoptosis. These regulators were studied in H19-7 cells, an SV40 T^ts-immortalized rat hippocampal neuronal cell line that can be differentiated with basic fibroblast growth factor at the nonpermissive temperature, resulting in a rapid attrition of cells by apoptosis. PCD occurred by two mechanisms in H19-7 cells: The first was initiated by removal of serum from undifferentiated cells, and the second was a consequence of neuronal differentiation. In differentiated H19-7 cells, the survival time was increased by both human bcl-2 and bcl-x_L, and this could be reversed by bcl-x_S.Addition of a peptide inhibitor of the ICE enzyme family to H19-7 cells resulted in a transient protection against differentiation-associated apoptosis, whereas no further protection was observed in the BCL-2- or BCL-X_L-expressing cells. Shifting the differentiated cells to 33°C to inactivate p53 did not significantly affect the apoptotic process, indicating that apoptosis induced by neuronal differentiation is not dependent on the continued presence of p53. By contrast, in undifferentiated cells, cell loss induced by transfer to serum-free media occurred more rapidly on inactivation of large T, consistent with p53 involvement. This medium-induced decrease in cell survival could not be rescued by the ICE inhibitor but was partially rescued by BCL-2 or BCL-X_L. Furthermore, studies involving expression of BCL-2 and BCL-X_L alone or together revealed differences in the survival dependent on the cellular environment. These results suggest that apoptosis of neuronal cellsoccurs by at least two processes: one in undifferentiated cells initiated by removal of serum and one linked to differentiation. The data implicate the ICE enzyme family but not p53 in apoptosis induced by differentiation and demonstrate that either BCL-2 or BCL-X_L can prolong the survival of differentiated neuronal cells.     

The pulling,pushing and fusing of lens fibers

Lens development and differentiation are intricate and complex processes characterized by distinct molecular and morphological changes. The growth of a transparent lens involves proliferation of the epithelial cells and their subsequent differentiation into secondary fiber cells. Prior to differentiation, epithelial cells at the lens equator exit from the cell cycle and elongate into long, ribbon-like cells. Fiber cell elongation takes place bidirectionally as fiber tips migrate both anteriorly and posteriorly along the apical surface of the epithelium and inner surface of the capsule, respectively. The differentiating fiber cells move inward from the periphery to the center of the lens on a continuous basis as the lens grows throughout life. Finally, when fiber cells reach the center or suture line, their basal and apical tips detach from the epithelium and capsule, respectively, and interlock with cells from the opposite direction of the lens and form the suture line. Further, symmetric packing of fiber cells and degradation of most of the cellular organelle during fiber cell terminal differentiation are crucial for lens transparency. These sequential events are presumed to depend on cytoskeletal dynamics and cell adhesive interactions; however, our knowledge of regulation of lens fiber cell cytosketal reorganization, cell adhesive interactions and mechanotransduction, and their role in lens morphogenesis and function is limited at present. Recent biochemical and molecular studies have targeted cytoskeletal signaling proteins, including Rho GTPases, Abl kinase interacting proteins, cell adhesion molecules, myosin II, Src kinase and phosphoinositide 3-kinase in the developing chicken and mouse lens and characterized components of the fiber cell basal membrane complex. These studies have begun to unravel the vital role of cytoskeletal proteins and their regulatory pathways in control of lens morphogenesis, fiber cell elongation, migration, differentiation, survival and mechanical properties.     

Crystallins during Xenopus laevis free lens formation

Summary The ontogeny and localization of crystallins during free lens development (i.e. lens development without the optic vesicle) were investigated in Xenopus laevis using the indirect immunofluorescence staining method with an antiserum raised against homologous total lens soluble proteins. Since the developing free lenses pass through stages similar to those of the lenses regenerated from the inner cell layer of the outer cornea following lentectomy in the same species Freeman's classification was used to identify the stages of free lens development. The first appearance of a positive reaction occurred at early stage IV in a number of cells in an area where future lens fibre cells would develop. With further differentiation of the free lens more and more cells in the fibre area started to show a positive reaction and the first positive reaction in the epithelium was observed late in stage V. Histological examination revealed that a fully differentiated free lens and a normally developed lens are similar but that the free lens is smaller.     

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.     

Studies on the nature and localization of acid phosphatase in normale and lens-regenerating urodele eyes. I. Histochemical localization

Histochemical procedures for acid phosphatase in normal and lens-regenerating eyes of the urodele Diemictylus viridescens demonstrate activity in a variety of structures. In the normal urodele eye, acid phosphatase is present in conjunctival and corneal epithelial cells and associated glands, in blood vessel endothelium and posterior epithelial cells of the iris, in the anterior lens epithelium, and in the cytoplasm of the optic nerve. Acid phosphatase in the lens-regenerating eye is localized in the same structures as in the normal eye as well as in increased amounts in the corneal epithelial cells and stromal macrophages at the lentectomy wound site and in the posterior portion of the developing lens during completion of differentiation of primary into mature lens fibers characterized by loss of many intracellular organelles. On the basis of these histochemical findings, it is proposed that hydrolytic lysosomal enzymes play an important role in the processes of cellular and intracellular destruction and synthesis which occur during Wolffian lens regeneration in the urodele.     

Lens-Specific Expression of PDGF-A Alters Lens Growth and Development

The vertebrate lens provides anin vivomodel to study the molecular mechanisms by which growth factors influence development decisions. In this study, we have investigated the expression patterns of platelet-derived growth factor (PDGF) and PDGF receptors during murine eye development byin situhybridization. Postnatally, PDGF-A is highly expressed in the iris and ciliary body, the ocular tissues closest to the germinative zone of the lens, a region where most proliferation of lens epithelial cells occurs. PDGF-A is also present in the corneal endothelium anterior to the lens epithelium in embryonic and early postnatal eyes. PDGF-B is expressed in the iris and ciliary body as well as in the vascular cells which surround the lens during early eye development. In the lens, expression of PDGF-α receptor (PDGF-αR), a receptor that can bind both PDGF-A and PDGF-B, is restricted to the lens epithelium throughout life. The expression of PDGF-αR in the lens epithelial cells and PDGF (A- and B-chains) in the ocular tissues adjacent to the lens suggests that PDGF signaling may play a key role in regulating lens development. To further examine how PDGF affects lens developmentin vivo,we generated transgenic mice that express human PDGF-A in the lens under the control of the αA-crystallin promoter. The transgenic mice exhibit lenticular defects that result in cataracts. The percentage of surface epithelial cells in S-phase is increased in transgenic lenses compared to their nontransgenic littermates. Higher than normal levels of cyclin A and cyclin D2 expression were also detected in transgenic lens epithelium. These results together suggest that PDGF-A can induce a proliferative response in lens epithelial cells. The lens epithelial cells in the transgenic mice also exhibit characteristics of differentiating fiber cells. For example, the transgenic lens epithelial cells are slightly elongated, contain larger and less condensed nuclei, and express fiber-cell-specific β-crystallins. Our results suggest that PDGF-A normally acts as a proliferative factor for the lens epithelial cellsin vivo.Elevated levels of PDGF-A enhance proliferation, but also appear to induce some aspects of the fiber cell differentiation pathway.