Stress Protein and Crystallin Synthesis During Heat Shock and Transdifferentiation of Embryonic Chick Neural Retina Cells

Embryonic chick neural retina responds to heat shock by the synthesis of "stress" polypeptides with molecular weights of 85 and 70 kd. Both stress proteins are synthesised from newly-transcribed messenger RNA. Sodium arsenite induces an additional stress protein of MW 25 kd. The heat shock response does not change during culture and subsequent transdifferentiation, and crystallin synthesis is not coinducible with the heat-shock proteins. We have also examined the pattern of protein synthesis at various stages of culture in both monolayer and aggregate systems; although changes in the protein synthetic profine are evident, there is no stress protein induction above basal levels at any time. Whilst mammalian α crystallin (B₂ chain) exhibits considerable homology to four small Drosophila heat-shock proteins, no significant antigenic similarity is apparent between δ crystallin and the major avian heat shock proteins. Thus during transdifferentiation, (a) the crystallin proteins do not behave in a manner analogous to stress proteins; moreover (b) crystallin production is not mediated by stress proteins resulting from a culture-induced stress response.     

Expression of Toxin Receptors on Cell Surfaces in Transdifferentiating Cultures of Neural Retina

It has often been asked which of the cell types found during the early stages of culturing embryonic chick neural retina can undergo transdifferentiation into lens in vitro. Since neuronal cell-surface toxin receptors are maintained in NR cultures for much longer than internal neuronal enzymes (e.g. choline acetyltransferase), and since the transdifferentiation process can be greatly accelerated by preparing reaggregates of neural retina cells after about 10 days of preculture as "monolayers", a direct test of this question became feasible. 7 or 9 day embryonic chick neural retina cells, precultured for 10–12 days as monolayers, were dissociated and reaggregated under continuous gyration. Reaggregates were maintained for 8 days in the presence of either tetanus toxin or FITC-conjugated α-bungarotoxin, to permit surface-bound toxins to become internalised via receptor turnover. The reaggregates were then dissociated, stained with rabbit antitoxin and FITC-conjugated anti-antibody in the case of tetanus toxin-labelled material, and restained with a rat or mouse antibody against chick δ crystallin followed by the appropriate rhodamine-conjugated anti-antibody. Although both FITC/toxin-labelled cells (putative neurones) and rhodamine/δ crystallin-labelled cells (transdifferentiated lens cells) were abundant, no examples of double-labelled cells were observed with 9 day starting material, and only a very few with 7 day starting material. We conclude that the vast majority of differentiated neuronal cells expressing surface receptors for these toxins do not transdifferentiate directly into lens cells.     

Determination of Chick Neuro-retinal Cells in Culture: Serum Factors Acting between 12 and 20 Days of Culture Influence the Extent of Subsequent Lens Cell Formation

Embryonic chick neuroretinal cells transdifferentiate into lens cells during culture in media containing foetal calf serum (F). This process is largely inhibited if horse serum plus supplementary glucose (Hg) is substituted for F. This paper explores the effect of medium changeover (from F to Hg or vice versa ) on the subsequent appearance of lens-specific δ-crystallin. If cultures are changed from Hg to F up to 12 days of culture, δ-production at 40 days is similar to that for controls maintained in F throughout. Changeovers between 14 and 17 days progressively inhibit subsequent δ production, and after 19 days in Hg, lens transdifferentiation cannot be induced by F. Conversely, if cultures are maintained in F for up to 17 days, a changeover to Hg blocks transdifferentiation, whereas similar transfers performed after 19 days give increased δ production. These results suggest that some retinal cells which will eventually form lens in vitro become so determined between the 12th and 20th days of culture. A mixture of 50% Hg and 50% F medium (FHg) does not support δ production even after 60 days, but in the absence of supplementary glucose (FH), δ appears in considerable amounts by 30 days.     

COMPARISON OF NEURONAL AND LENS PHENOTYPE EXPRESSION IN THE TRANSDIFFERENTIATING CULTURES OF NUERAL RETINA WITH DIFFERENT CULTURE MEDIA*

The effects of three different culture media (Eagle's MEM, F-12 and L-15) on the transdifferentiation of 8-day chick embryonic neural retina into lens cells, were examined with respect to the expression of two phenotypes. One type referred to neuronal specificity (as represented by the level of cholineacetyl-transferase, CAT, activity) and the other to lens specificity (as represented by content of α-and δ-crystallin). In 7-day cell cultures before the visible differentiation of lentoid bodies, CAT activity was detected in all media. But, its level was about 9 times higher in cultures with L-15 than in those with MEM and 3 times higher than in F-12. In 26-day cultures, CAT activity was practically undetectable. The production of α-and δ-crystallin was detected in cultures at 26 days. There were quantitative differences in the crystallin content with different media, and it was highest in cultures with L-15. The results indicate that conditions most favourable to the maintenance of the neuronal specificity in cell cultures of neural retina, can also support the most extensive transdifferentiation. The possibility of direct transdifferentiation of once neuronally specified cells into lens cells in cultures with L-15 has been suggested to explain the present results.     

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.     

The ability of the epithelium of diencephalic origin to differentiate into cells of the ocular lens.

After the discovery that in adult salamanders following lentectomy a new, functional lens develops by transdifferentiation (cell-type conversion) of previously depigmented epithelial cells of the iris (Wolffian lens regeneration), this phenomenon has been intensively studied by various experimental approaches. During the last two decades it was shown that pleiomorphic aggregates of atypical lens cells (lentoids) differentiated in reaggregates of dissociated cells of the chick neural retina and in spread cell cultures of the pigmented epithelium of the iris and retina, of the neural retina and the pineal gland of the chick embryo. The neural retina of human fetuses and adults also displayed this capacity. We showed that lentoids developed at a low incidence in renal isografts of rat embryonic shields or isolated embryonic ectoderm and of lentectomized eyes of rat fetuses, as well as in organ cultures of rat embryonic shields in chemically defined media. The addition of transferrin significantly increased the incidence of differentiation of lentoids in explants. In both renal isografts and explants in vitro a continuous transformation of retinal epithelial cells into atypical lens cells was observed. In renal isografts lentoids were also observed to originate from the ependyma of the brain ventricle. All tissues having the capacity to convert into lens cells belong to the diencephalon in a broad sense. Evolutionary aspects of this feature are discussed.     

DIFFERENTIATION AND DEDIFFERENTIATION OF RAT LENS EPITHELIAL CELLS IN SHORT- AND LONG-TERM CULTURES

The crystallin synthesis of rat lens cells in cell culture systems was studied in relevance to their terminal differentiation into lens fibers. SDS-gel electrophoresis combined with several immunological techniques showed that γ-crystallin is a fiber-specific lens protein and is not localized in the epithelium of either newborn or adult lenses. When lens epithelial cells of newborn rats were cultured in vitro , α-crystaIlin was detected in many, but not all, of cells cultured for 10 days. Cells with α-crystallin gradually changed their shape into a flattened filmy form and finally differentiated into lentoid bodies. The differentiation of lentoid bodies was also found in cultures of epithelial cells obtained from adult lenses. The molecular constitution of lentoid bodies was the same as that of lens fibers in situ . The differentiation of lentoid bodies occurred successively for 5 months in cultures of lens epithelial cells. Most of the proliferating cells, however, lost α-crystallin during the culture period. Thereafter, they did not show any sign of further differentiation into lens fibers. Four clonal lines were established from these cells. One protein which is specific to the lens epithelium and the neural retina in situ (tentatively named as β_u-crystallin) was maintained in all lines, suggesting that some specific properties of ocular cells remain in the lined cells.     

The pattern of DNA methylation in the delta-crystallin genes in transdifferentiating neural retina cultures

Terminally differentiated lens fibre cells are formed in the vertebrate lens throughout life. Lens fibre cells may also be obtained by an in vitro process termed transdifferentiation, from certain tissues of different developmental origin from lens, such as embryo neural retina. delta-Crystallin is the major protein in the chick embryo lens fibre cells, and also in transdifferentiated lens cells obtained from cultured embryonic neural retina. Lens crystallin proteins and mRNA are present at low levels in the intact embryonic neural retina but are no longer detectable in the early stages of neural retina cell culture. However, levels rise steeply in the later stages and crystallins become the major products in terminally transdifferentiating neural retina cultures. We have used this system to test the hypothesis that the patterns of DNA methylation in particular genes are correlated with gene expression. A number of developmentally regulated genes have been found to be undermethylated in tissues where they are expressed, and methylated in tissues where they are not. However this correspondence does not always hold true. Eight-day-old embryonic neural retina was cultured for the period of time during which crystallin gene expression increases 100-fold. DNA methylation in the delta-crystallin gene region was analysed at several stages of cell culture by using the restriction endonucleases HpaII and MspI which cleave at the sequence CCGG. The former enzyme cannot cleave internally methylated cytosine (CmCGG) while the latter cannot cleave externally methylated cytosine (mCCGG). We detect no change in the methylation of CCGG sites within the delta-crystallin gene regions during transdifferentiation. Since dramatic changes in delta-crystallin gene expression occur during this process we conclude that large scale alterations in the pattern of DNA methylation are not a necessary accompaniment to changes in gene activity.     

Biochemical and immunological studies of lentoid formation in cultures of embryonic chick neural retina and day-old chick lens epithelium

During long-term cell culture of 8-day embryonic chick neural retina, lentoid bodies containing lens crystallins are developed. Although very low levels of crystallin can be detected in the embryonic neural retina, gross synthesis of each major crystallin class (α, anodal β, cathodal β, and δ) begins only after 12–16 days in culture. This occurs at least 10 days before lentoid bodies can be distinguished by eye. The concentration of each crystallin class was determined during lentoid development in cultures of both neural retina and lens epithelium. The proportions of crystallins in lentoid-containing cultures do not resemble those of embryonic lens fibres. Comparisons between two chick strains (N and Hy-1) differing in their growth rates revealed several differences in the crystallin compositions of lentoid bodies. These differences imply independent quantitative regulation for most or all of the crystallins.     

Differential effects of culture media on normal and foreign differentiation pathways followed by chick embryo neuroretinal cells in vitro

Abstract. Three different culture media, Ham's F-12, medium 199, and Eagle's minimal essential medium (MEM), were compared with respect to the expression of neuronal (choline acetyl transferase activity: CAT) and glial (hydrocortisone-induced glutamine synthetase activity; GSase) markers of normal differentiation in cultures of 9-day chick embryo neuroretinal cells, and also with respect to the accumulation of a lens marker (δ crystallin) during so-called 'transdifferentiation' in these cultures.
MEM allows transient expression of both CAT and GSase activities in early cultures, but also permits extensive δ crystallin accumulation at later stages. F-12 medium gives somewhat higher levels of CAT and GSase activities, the former being noticeably prolonged as compared with parallel MEM cultures; δ crystallin accumulation, however, is largely inhibited in F-12 cultures. By contrast, medium 199 permits only low levels of CAT and GSase activities, perhaps because the neuronal cells are distributed individually over the glial cell sheet in 199 cultures, rather than forming aggregates as in MEM or F–12 cultures. Medium 199 also blocks δ crystallin accumulation.
The results of medium changeover between 'transdifferentiation'-permissive (MEM) and non-permissive (199, F-12) conditions suggest: (a) that potential lens precursor cells (whatever their nature) survive in F-12 medium for prolonged periods without extensive expression of the lens phenotype; (b) that such precursor cells become committed to subsequent differentiation as lens cells between 10 and 20 days of culture in permissive MEM medium (as judged by the accumulation of δ crystallin following transfer into F-12); and (c) that medium 199 can block expression of the lens phenotype even in cells already committed (by the above criteria) to lens differentiation, as for instance after 30 days of preculture in MEM.     

AGE-DEPENDENT CHANGE IN THE TRANSDIFFERENTIATION ABILITY OF CHICK NEURAL RETINA IN CELL CULTURE*

We examined how the transdifferentiation ability of neural retinal cells into lens and/or pigment cells in call culture is changed with the development of the donor. Cells dissociated from neural retinas of chick embryos ranging from 3-day-old to the stage immediately before hatching and of 3-day-old chicks were cultured for about 60 days. The results clearly indicated that the transdifferentiation ability decreased with age. The latest developmental stage at which the differentiation of lens cells took place was in 18-day-old embryos. A gradual decrease in this ability was shown by the comparison of crystallin content in cultures prepared from embryos at different stages. The differentiation of pigment cells was recognized in cultures of neural retinas earlier than in 15-day-old embryos. Such loss of the ability of neural retinal cells to transdifferentiate into pigment cells earlier than into lens cells can be partially attributed to inhibitory factors accumulated in medium conditioned with many neuronal cells present in cultures.     

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.     

Embryonic Serum Factors Required for Transdifferentiation of Chick Embryo Neuroretinal Cells in Culture

The accumulation of δ crystallin (chick lens marker) in cultures of 9 day chick embryo neuroretinal cells is strongly promoted by chick embryo extract (CEE) or foetal calf serum (FCS), but much less so by adult sera (horse, chicken and newborn bovine serum). The "transdifferentiation-promoting" (TP) activity of FCS is absent from dialysed FCS but is largely recovered in the initial dialysis medium (F_DM). Similarly, the initial dialysis medium from CEE (E_DM) shows strong TP activity, whereas that from chicken or from horse serum does not. We conclude that the proposed TP factor(s) is (are) of relatively low molecular weight. By contrast, horse serum contains macromolecular factor(s) able to inhibit the TP activity of E_DM or F_DM. Rapid loss of neuronal cells (including those expressing choline acetyltransferase activity) is also observed in media based on F_DM, though whether this effect is mediated by the proposed TP factor(s) has not been determined. The TP activity is not directly related to growth rate or cell density, since cultures in F_DM alone grow poorly yet still accumulate δ crystallin.     

Production of crystallins and lens-like structures in differentiation-induced neoplastic pigment cells (goldfish erythrophoroma cells) in vitro

Abstract. We examined the crystallins present in lens-like cell aggregates produced by goldfish erythrophoroma (tumors of integumental erythrophores) cells in vitro using a combination of Sephadex-G-200 gel filtration, one- and two-dimensional sodium-dodecyl-sulfate/poly-acryl-amide gel electrophoresis, immunoblotting, and indirect immunofluorescence assays. The two studied neoplastic pigment cell lines, GEM 81 and GEM 218, formed small, spherical, transparent cell aggregates, resembling lentoid bodies. within the cell mounds of monolayer cultures after treatment with dimethylsulfoxide (DMSO) and autologous serum. Partial purification of a water-soluble extract of such lens-like cell aggregates and subsequent immunoblotting using antibodies (polyclonal) against newt whole lens proteins revealed the presence of about 20 unequivocally conjugated peptides with molecular masses of 19-27 kilodaltons. From their antigenicity and their behavior during gel filtration and electrophoresis, most of these peptides were identified as either α or β-form crystallins. Immunofluorescence microscopy using antibodies to newt whole lens proteins revealed intense fluorescence in the lens-like cell aggregates formed by these erythrophoroma cells, whereas the cell mounds in cultures of the same cell lines that had not been subjected to differentiation induction were almost unlabeled. Thus, goldfish erythrophoroma cells appear to be capable of crystallin production as well as the formation of lens-like cell aggregates upon the induction of differentiation. There is little available information indicating that normal pigment cells are capable of lens formation and crystallin synthesis during vertebrate ontogeny, and thus it is possible that neoplastic transformation of pigment cells is associated with the acquisition of the ability to produce crystallins.     

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.     

α, βI, βII, δ, and ε Protein Kinase C Isoforms and Compound Activity in the Sciatic Nerve of Normal and Diabetic Rats

Abstract: Defective protein kinase C (PKC) has been implicated in impaired Na⁺,K⁺-ATPase activity in the sciatic nerve of streptozotocin-induced diabetic rats. In the present study, α, βI, βII, γ, δ, and ε isoform-specific antibodies were used in parallel to the measurement of compound PKC activity for the characterization of PKC distribution and isoform expression in sciatic nerves of normal and diabetic rats. To distinguish isoform expression between the axonal and glial compartments, PKC isoforms were evaluated in nerves subjected to Wallerian degeneration and in a pure primary Schwann cell culture. α, βI, βII, δ, and ε but no γ isoforms were detected in sciatic nerve. Similar immunoreactivity was observed in degenerated nerves 3–4 days after transection except for diminished βI and ε species; in Schwann cell cultures, only α, βII, δ, and ε were detected. In normal nerves, two-thirds of PKC compound activity was found in the cytosol and 50% of total enzyme activity translocated to the Na⁺,K⁺-ATPase-enriched membrane fraction with phorbol myristate acetate. Similar redistribution patterns were observed for the immunoreactivity of all isoforms with the exception of δ, which did not translocate to the membrane with phorbol myristate acetate. No abnormality in compound PKC activity, in the immunoreactive intensity, or in the distribution of PKC isoforms could be detected in rat sciatic nerve after 6–12 weeks of diabetes. Thus, defective activation rather than decreased intrinsic PKC activity may occur in diabetic neuropathy.