State of differentiation of bovine epithelial lens cells in vitro. Modulation of the synthesis and of the polymerization of specific proteins (crystallins) and non-specific proteins in relation to cell divisions

Cell division and aging of the organism

The capacity to regenerate cell compartments through cell proliferation is an important characteristic of many developed metazoan tissues. Pre- and post-natal development proceeds through the modifications occurring during cell division. Experiments with cultivated cells showed that cell proliferation originates changes in cell functions and coordinations that contribute to aging and senescence. The implications of the finite cell proliferation to aging of the organism is not the accumulation of cells at the end of their life cycle, but rather the drift in cell function created by cell division. Comparative gerontology shows that the regulation of the length of telomeres has no implications for aging. On the other hand there are interspecies differences in regard to the somatic cell division potential that seem to be related with the "plasticity" of the genome and with longevity, which should be viewed independently of the aging phenomenon. Telomeres may play a role in this plasticity through the regulation of chromosome recombination, and via the latter also in development.

Crystallin gene expression in the process of lentoidogenesis in cultures of chicken lens epithelial cells

One alpha B- and three different beta-crystallin cDNA clones were isolated from a chicken lens cDNA library by using anti-crystallin antibodies. The sequence of alpha B-crystallin cDNA showed more than 70% homology with exons of alpha B-crystallin genes of the human and hamster. Two beta-crystallin cDNAs showed almost identical sequences with previously reported chicken beta B1- and beta A3/A1-crystallin genes. The remainder showed 80% homology of sequence with bovine beta B2-crystalline cDNA. Using these newly cloned cDNAs, in addition to cDNAs of alpha A- and delta-crystallin, we examined the expression pattern of these crystallins in the process of lentoidogenesis of cultured lens epithelial cells of the chicken. All crystallins except beta-crystallins were expressed through the period of cell culture, but three beta-crystallins were expressed only after the confluent stage. These results suggest that: (1) alpha A-, alpha B- and delta-crystallin cDNAs can be used to detect differentiation of the lens epithelial cell; and (2) beta-crystallin cDNAs are superior in the detection of chicken lens fibre differentiation in vitro to delta-crystallin cDNA, which is ectopically expressed by various non-lenticular tissues.

Study of crystallin expression in human lens epithelial cells during differentiation in culture and in non-lenticular tissues

Crystallin expression in human lens epithelial cells in culture and a number of non-lenticular tissues was studied by the technique of immunoblotting using monoclonal antibodies. The expression of alpha A, beta 5 and beta 6 crystallins per unit number of cells increased with passage number while alpha B appeared to be constant Lentoid bodies derived from cultured human lens epithelial cells not only expressed gamma-crystallin and MP26 as previously demonstrated, but also produced alpha A, alpha B, beta 5 and beta 6 crystallins. In human non-lenticular tissues including ciliary body, vitreous body, neural retina, cultured retinal pigment epithelial cells and scleral fibroblasts, alpha B-crystallin was detected, but was undetectable in cornea and iris. Alpha A was present only in the lens. These studies demonstrate that HLE cells maintain the ability to synthesize crystallins through several passages. Following differentiation, they not only synthesize gamma-crystallin and MP26 but continue to express alpha- and beta-crystallins similar to differentiated lens fiber cells in vivo. Consistent with previous observations, the expression of alpha B-crystallin does not appear to be specific for the lens.

Evidence for ATP and ubiquitin dependent degradation of proteins in cultured bovine lens epithelial cells

Degradation of endogenous lens proteins has been difficult to show under physiological conditions using lens tissue preparations. In contrast, active proteolytic systems in cultured bovine lens epithelial (BLE) cells have been demonstrated previously. BLE cells also contain ubiquitin, a 76 amino-acid polypeptide which is conjugated to proteins in an ATP/Mg(2+)-dependent process prior to their cytosolic proteolysis. In this study, we show that histone H2A, alpha-crystallin, and actin are conjugated to ubiquitin, resulting in higher molecular mass species, which are detected by anti-ubiquitin antibodies. These proteins are also degraded in cell-free assays containing BLE cell supernatants under physiological conditions in an ATP/Mg(2+)-dependent manner. Observation of 125I-labeled proteolytic fragments was made after SDS polyacrylamide gel electrophoresis of the assays. Quantitation of trichloroacetic acid-soluble radiolabeled fragments generated in the presence of ATP/Mg2+ revealed that, with BLE cell supernatant, 25% of the histone H2A was degraded in 3 hr. Proteolysis of alpha-crystallin and actin amounted to 2.3% and 2.9%, respectively. The requirement of ATP/Mg2+ for proteolysis and the observation of ubiquitin conjugation to the same proteins is consistent with the presence of a ubiquitin-dependent proteolytic pathway in BLE cells. Additionally, in this study the BLE cell proteases were even more active on some substrates than the reticulocyte ubiquitin/ATP-dependent proteolytic system.

Tissue- and species-specific promoter elements of rat gamma-crystallin genes

The 5' flanking regions of the six rat gamma-crystallin genes (gamma A-gamma F) are all capable of conferring lens-specific expression to the bacterial chloramphenicol acetyl transferase (CAT) reporter gene in either transdifferentiating chicken neural retina cells or mouse lens epithelial cells. Deletion mapping of the most active gamma-crystallin promoter region, the gamma D region, showed that at least three elements are required for maximal expression in mouse lens epithelial cells: element(s) located between -200 and -106, a conserved CG rich region around position -75, and a CG stretch around -15. The region between -200 and -106 was dispensable in transdifferentiating chicken neural retina cells, which instead required the region between -106 and -78. The maximal activity of the gamma E and gamma F promoters was also dependent upon the integrity of the conserved CG region located around -75. A synthetic oligonucleotide containing this sequence was capable of lens-specific enhancement of the activity of the tk promoter in transdifferentiating chicken neural retina cells but not in mouse lens epithelial cells. Our results further show that this region may contain a silencer element, active in non-lens tissues, as well.

Induction of de novo synthesis of crystalline lenses in aphakic rabbits

The mammalian lens, like other ectodermal tissues, can regenerate itself given the proper environment. Endocapsular phacoemulsification of adult rabbit lenses was performed. A lens capsular bag with posterior and anterior lens capsule relatively intact was left in the eye. Regrowth of material in the capsular bag was followed by slit lamp biomicroscopy and photography over a 12-month period. Histopathology of the new material showed regions of relatively normal epithelial cells and lens fibers as well as regions where growth was irregular. All major lens crystallin classes were present in the regenerated lens. Several specific crystallin subunits, known to arise by post-translational modification of primary gene products, were absent or present in abnormally low concentrations.

Human fetal lens epithelial cells in culture: an in vitro model for the study of crystallin expression and lens differentiation

We have cultured and passaged human fetal lens epithelial cells. Cultured cells exhibited hexagonal, cuboidal shape typical of epithelial cells. Unlike previous observations made with cultured mammalian lens epithelial cells, indirect immunofluorescence and temporal analysis of 35S-labeled proteins demonstrated undiminished levels of alpha B-crystallin in primary, secondary, and tertiary cultures. Among the alpha-crystallins only alpha B synthesis was detected. Two dimensional gel electrophoresis indicated the presence of alpha B2 and no alpha B1. beta B2-crystallin, a fiber cell specific protein hardly detectable in primary cultures, increased significantly upon passaging. Human fetal lens epithelial cell cultures, described in this report, thus present a useful in vitro model for the study of lens epithelial cell differentiation and its pathological manifestations.

Maintenance of the synthesis of alpha B-crystallin and progressive expression of beta Bp-crystallin in human fetal lens epithelial cells in culture

We have cultured and maintained human fetal lens epithelial cells for several months in primary, secondary, and tertiary culture(s). These cells show unabated synthesis of alpha B-crystallin (alpha B), a lens epithelial cell-specific marker, and progressive expression of beta Bp-crystallin (beta Bp), a major polypeptide of the differentiated lens fiber cells in vivo. Interestingly, the expression of beta Bp was found to be dependent on subculturing of the cells and not on the age of cultures. These observations demonstrate that human fetal lens epithelial cells can be cultured in vitro without the loss of lens specific characteristics and with commitment to differentiation at the biochemical level.

Crystallins and their synthesis in human lens epithelial cells in tissue culture

Explants of epithelial cells from young human lenses of 5-12 months of age, obtained from patients who underwent surgery for retinopathy of prematurity, were cultured in Dulbecco's modified Eagle's medium supplemented with 20% fetal calf serum. Without exception, every piece of the anterior capsule explant showed cell outgrowth within 48-72 h and resulted in confluent monolayer culture within 2 weeks. From these monolayer cultures, two to three passages of subcultures were obtained by routinely seeding cells in a ratio of 1:4. The doubling times for these human lens epithelium (HLE) cultures during the first 4 weeks of two passages were found to be 24-36 h. In a majority of cultures through the first three passages, more than 12 population doublings were attained. However, no lentoid bodies were formed during this period. These cells were studied for the presence of crystallins and their synthesis. Using SDS-polyacrylamide gel electrophoresis, the presence of alpha- and beta-crystallins was demonstrated in HLE cells through three passages. The amount of alpha-crystallin in the first two passages amounted to nearly 13% of the total protein, but decreased significantly in the third passage. The presence of crystallins was corroborated by antibody reaction to the specific crystallins. Indirect immunofluorescence revealed the presence of actin and vimentin in these cell cultures. The synthesis of crystallins in HLE cultures was shown by the incorporation of [35S]methionine which was time dependent. The crystallin synthesis was found to decrease in third passage when the cell growth slowed down without consistent formation of confluent monolayer. These studies have demonstrated that primary cultures of HLE cells can be successfully grown from young lenses through several passages which continue to express the characteristic crystallins of the epithelial cells.

The influence of the genotype on the process of ageing of chick lens cells in vitro

We reported previously that changes in crystallin expression in differentiating long-term primary cultures of lens cells from five different chick genotypes are similar to those which occur in vivo between hatching and the 8-week-old adult. These changes followed a similar program in all genotypes but occurred more rapidly in cells from the fast-growing than from the slow-growing genotypes. The present study examines ageing changes in lens cell populations from the same five genotypes, over a 4-6 month period, using long-term serial subcultures. The capacity for lentoid differentiation was progressively lost, but the rate of loss was inversely related to the intrinsic growth rate of the cells of these genotypes, occurring at the first passage in the slowest-growing strain, while fifth passage cells of the fastest-growing strain still retained some lentoid-forming capacity. The rate of loss of crystallin expression was also inversely related to the genetic growth rate, but the sequence of changes appears to be nonrandom, since it was broadly similar in all genotypes, starting with a preferential loss of delta-crystallin, as occurs in vivo; although alpha- and beta-crystallins were undetectable in late dedifferentiated cultures, the capacity of the cells for their synthesis was still present. Cultures from both fast-growing genotypes eventually showed senescence, but those from all three slow-growing genotypes underwent transformation. The major cell component in late cultures of all genotypes was actin.

Transdifferentiated embryonic neuroretina cells: an in vitro system to study crystallin aggregation process

Transdifferentiated embryonic quail neuroretina cells synthesize in vitro crystallins (the lens-specific proteins) and form lentoid bodies (structures that mimic lens fiber cells) which also contain crystallins. A comparative study on the size of crystallins is reported in 7-day-old embryonic quail lenses, in 7-day-old embryonic quail transdifferentiated neuroretina cells (normal and MH2 transformed), and in isolated lentoid bodies. Analyses are performed using Superose FPLC in combination with SDS-PAGE and Western blot procedures. In quail lenses, an apparent 560-580-kDa alpha crystallin homopolymer is found and delta crystallin, the major avian lens protein, is detected as a 180-kDa tetramer. beta Crystallins, present in low amount within the 180-kDa peak, are a heterogeneous population composed of subunits of molecular weight identical to those found in chick lenses. In addition, an apparent 46-kDa monomeric delta crystallin is found. Normal and MH2-transformed neuroretina cultures produce an alpha crystallin polymer of lower molecular weight (450 kDa) and delta crystallin in a monomeric or dimeric form. The Western blot pattern of beta crystallins from MH2-transformed neuroretina cultures is strictly identical to that of quail lens beta crystallins. In particular, the beta B1 crystallin, which is specific to lens fiber cell differentiation, and the major beta 25-kDa crystallin are present. However, analysis of isolated lentoid bodies from normal transdifferentiated quail neuroretina cultures showed alpha and delta crystallins of comparable size to those found in lens extract, in particular the delta crystallin in tetrameric form. The lentoid body lens-like structure could favour the crystallin aggregation process.

Analysis of an inductive interaction between lens and neural retina in rats of different ages

Lens epithelial cells from neonatal rats cultured with neural retinas or neural retina-conditioned medium (RCM), undergo fibre differentiation. This is characterized by cell elongation, increased alpha-crystallin synthesis and the initiation of beta and gamma-crystallin synthesis. To determine if this tissue interaction continues in later life we developed an ELISA method to analyse patterns of alpha and beta-crystallin accumulation in epithelia from 3-day-, 10-day- and 21-day-old rats. Culture of lens epithelia with RCM resulted in the formation of multilayers of elongated fibres and the accumulation of alpha and beta-crystallins. The patterns of crystallin accumulation were essentially similar whether expressed as microgram crystallin per explant, or crystallin per DNA (ng per ng). alpha- and beta-Crystallins accumulated rapidly in explants after 2 days of culture in RCM, whereas explants grown in control medium showed no change in the crystallin levels from day 0 to day 10. Patterns of alpha- and beta-crystallin accumulation showed that there were no significant differences between the ability of lens epithelia from 3-day-, 10-day or 21-day-old rats to undergo fibre differentiation in response to RCM. Therefore we conclude that the inductive interaction between lens and neural retina is not restricted to embryonic or neonatal stages, but continues on throughout life maintaining normal patterns of fibre differentiation in the lens.

Retention of lens specificity in long-term cultures of diploid rabbit lens epithelial cells

Rabbit lens epithelial cells from newborn animals exhibited limited growth when cultured under standard conditions. Cell lines were generated when explants from individual lenses were cultured in medium supplemented with conditioned medium or untreated rabbit serum. All lines exhibited a stable epithelial morphology. One line, N/N1003A, was examined extensively with respect to its growth, ploidy, and maintenance of lens-specific functions. Cells at population-doubling level (pdl) 120 exhibited a normal chromosomal banding pattern, were diploid, were non-tumorigenic in vivo, did not grow in suspension culture, and did not exhibit sustained growth in medium supplemented with low concentrations of serum. The shape of the growth curves and the final density for cells at pdl 24 and 181 exposed to various concentrations of serum were identical. The cells showed no diminution in growth as a function of in vitro age. The cells retained lens-specific functions. Proteins were isolated from cells at pdl 40 and 170, and were separated on polyacrylamide gels. Western immunoblot analysis using antiserum to alpha-crystallin, a tissue-specific protein found in lens epithelial cells in vivo, indicated the presence of alpha-A- and alpha-B-crystallin polypeptides. The cells also contained the transcription factors required for activating the murine alpha-A-crystallin gene promoter, which is known to function with precise tissue specificity. When an expression vector including the bacterial chloramphenicol acetyltransferase (CAT) gene controlled by the alpha-A-crystallin gene promoter was introduced into the lens epithelial cells, the CAT gene was expressed.(ABSTRACT TRUNCATED AT 250 WORDS)

Alterations in crystallin gene expression during subculture of chick lens cells

We report here on the changes in crystallin gene expression during serial subculture of lens epithelial cells derived from day-old post-hatch chicks. Total cellular RNA from mass cultures were analysed by in vitro cell-free translation and by RNA blot (Northern) hybridization using a cloned delta-crystallin cDNA. Our results indicate that following subculture, lens epithelial cells which still retain the capacity for lens fibre differentiation (lentoid body formation) show a selective loss of delta-crystallin synthesis, and that this is related to the loss of delta-crystallin mRNA. The data suggest that older epithelial-cell populations give rise to lentoid bodies which in terms of crystallin gene expression closely resemble the later-formed cortical fibres of the adult chick lens. Tertiary cultures had an accelerated growth rate, formed no lentoids, contained no translatable alpha- or delta-crystallin mRNAs but still contained translatable beta-crystallin mRNAs.

Cytodifferentiation and tissue phenotype change during transformation of embryonic lens epithelium to mesenchyme-like cells in vitro

A number of adult and embryonic epithelia, when suspended within native type I collagen gels, give rise to elongate bipolar cells that migrate freely within the three-dimensional matrix. The morphology of these newly formed mesenchyme-like cells is indistinguishable from "true" mesenchymal cells at the light and ultrastructural level. In this report, we extend previous observations on the transformation of embryonic avian lens epithelium to mesenchyme-like cells. Lens epithelia, dissected from 12-day chick embryos, were cultured either within a collagen matrix or on a two-dimensional surface. Cells derived from explants on the surface of type I collagen express the epithelial phenotype. The cells form new basal lamina, continue to express delta-crystallin protein and secrete both type IV collagen and laminin. In contrast, epithelia suspended within collagen gels lose epithelial morphology, phenotype, and cytodifferentiation. The newly formed mesenchyme-like cells lack the ability to synthesize lens-specific delta-crystallin protein, type IV collagen, and laminin. They do, however, express type I collagen de novo, a characteristic of mesenchymal cells. The changes in cytodifferentiation and tissue phenotype which occur during the transformation are stable under the conditions studied here. When mesenchyme-like cells are removed from the gel and replated onto two-dimensional surfaces, they remain bipolar, will invade collagen matrices, and are unable to synthesize delta-crystallin protein.

Lens-specific expression of the chloramphenicol acetyltransferase gene promoted by 5' flanking sequences of the murine alpha A-crystallin gene in explanted chicken lens epithelia

We have developed a system using explanted embryonic chicken lens epithelia to express foreign recombinant genes containing crystallin DNA regulatory sequences introduced by calcium phosphate transfection. Optimal results were obtained with lens epithelia from 14-day embryos transfected 1 day after explantation and assayed 3 days later. When DNA sequences (-364 to +45) of the murine alpha A-crystallin gene were inserted in the pSVO-CAT expression vector of Gorman et al. [Gorman, C. M., Moffat, L. F. & Howard, B. H. (1982) Mol. Cell. Biol. 2, 1044-1051] in the same orientation as in the crystallin gene, they promoted chloramphenicol acetyltransferase (CAT; EC 2.3.1.28) activity in the transfected epithelia. Sequences 87 to 364 base pairs upstream from the murine gene cap site were required for CAT gene expression. These crystallin gene regulatory sequences did not promote CAT expression in primary cultures of embryonic chicken fibroblasts or other nonlens cells. By contrast, the long terminal repeat of Rous sarcoma virus and the early promoter of simian virus 40 promoted CAT activity in lens and nonlens cells. Our experiments thus demonstrate that the explanted embryonic chicken lens epithelium is an advantageous recipient for identifying lens-cell-specific regulatory sequences of crystallin genes and implicate a DNA region upstream of the "TATA box" for regulation of the murine alpha A-crystallin gene. These experiments also suggest that explanted epithelia from other tissues may be useful for studying the expression of foreign genes.

A comparison of the changing patterns of crystallin expression in vivo, in long-term primary cultures in vitro and in response to a carcinogen

Changes in the differentiation of day-old chick lens epithelium in long-term primary culture conditions were investigated by sodium dodecyl sulphate-polyacrylamide electrophoresis, using integrating densitometry to assess the relative levels of accumulated crystallin and non-crystallin polypeptides and fluorography to assess their relative levels of synthesis. The main changes during the culture period included a relative decline in the proportion of actin and other non-crystallins, an initial increase in 48K delta-crystallin expression followed by a decline and a shift in beta-crystallin expression from a relative preponderance of the 24K and 23K polypeptides to a relative preponderance of the 24K and 22K polypeptides. At all stages the level of the 19K alpha-crystallin was higher than that of the 20K alpha-crystallin polypeptide. In general, the changes in the pattern of expression of these polypeptides in culture were similar to those observed in vivo in the post-hatch chick, suggesting an intrinsic programme of crystallin expression. The changes in gene expression were also tested indirectly by brief exposure of the cells in vitro to a carcinogen, N-methyl-N'-nitro-N-nitrosoguanidine (MNNG) which is known to produce, in some systems, effects related to the status of the cell at the time of treatment. The effects were found to depend on the stage of differentiation of the culture at the time of treatment. Treatment on day 1 of culture prevented later lentoid formation and severely reduced the expression of all crystallins with the exception of the 34K beta-crystallin polypeptide. Actin was the most abundant soluble cell component, and a proportion of the cells acquired a fibroblast-like morphology. Treatment with MNNG on day 7 led to a delay in lentoid formation and a differential reduction of the synthesis of crystallin polypeptides, whereas the treatment of already differentiated cultures on day 18 and to lesser extents on days 27, 45 and 55, respectively, led to an increase in crystallin synthesis relative to controls. These results suggest that this programme of crystallin gene expression becomes more resistant to change with increasing epithelial differentiation.

Interaction of bovine epithelial lens (BEL) cells with extracellular matrix (ECM) and eye-derived growth factor (EDGF). I. Effects on short-term adhesiveness and on long-term organization of the culture

A growth factor (EDGF) derived from the retina controls the proliferation and shape of adult bovine epithelial lens (BEL) cells in vitro as well as extracellular matrix (ECM) assembly. In order to analyse this mechanism and the specificity of the interactions between BEL cells and the extracellular matrix we have investigated the adhesion and growth of BEL cells on various substrata (fibronectin, laminin, ECM). BEL cells treated with EDGF adhered more slowly to plastic Petri dishes than untreated cells, in part due to EDGF inhibition of fibronectin deposition. The untreated BEL cells spread less well on ECM or laminin than on fibronectin-coated plastic. The preferential adhesiveness of BEL cells on fibronectin vs laminin was confirmed by attachment experiments performed on replicas of SDS-PAGE of these proteins. However, in long-term cultures, 8 days after seeding, BEL cells were very differently arranged on plastic or on ECM. ECM by itself did not increase the proliferation rate but helped to restore an organized cell monolayer. BEL cells stimulated to grow on ECM by treatment with EDGF exhibited at least transiently contact inhibition producing a perfectly organized epithelium similar to the one observed in vivo. These results suggest specific interactions between ECM or ECM components with BEL cell that restrain excessive cell spreading and restore an original polarized phenotype of the cells seen in vivo.