Lens fiber organization in four avian species: a scanning electron microscopic study

The three-dimensional organization of the eye lenses of the chicken, the canary, the song-thrush and the kestrel was studied using light and scanning electron microscopy. The lenses of birds are characterized by the presence of two distinct compartments: the annular pad and the main lens body, separated by a cavum lenticuli. The annular pad fibers had a hexagonal circumference all contained a round nucleus and except for the canary were smooth-surfaced and lacking anchoring devices. In the canary, however, the annular pad fibers were studded with edge protrusions and ball-and-socket junctions. The semicircular main lens body fibers of all four species were studded with ball-and-socket junctions and edge protrusions. In contrast with mammals these anchoring devices were present throughout the lens up to the embryonal nucleus. Superficially the main lens body fibers were extremely flat. Additionally membrane elevations and depressions and globular elements were found on these central fibers in three species, the kestrel being the exception. At the transition between annular pad and main lens body the fibers turned their course and the nuclei became oval and disappeared in the deeper aspect of the main lens body. The cavum lenticuli was filled with globules tied off from the annular pad fibers. It seems attractive to assume that the presence of a separated annular pad, a cavum lenticuli filled with globular elements, the extreme flatness of the superficial central fibers and the studding of these central fibers with anchoring devices up to the embryonal nucleus are morphological expressions of the mouldability of the bird's eye lenses and consequently would explain their efficient accommodative mechanism including formation of a lenticonus. The presence of nuclei in the annular pad fibers and their typical change at the transitional zone between annular pad and main lens body are suggestive for a two-phased differentiation in bird's lens fibers: differentiation of the germinative epithelial cells to annular pad fibers which migrate to the main lens body after which they differentiate further to main lens body fibers.     

The 23-kDa polypeptide from Common Frog lens: isolation,characteristics and cellular localization

The major water-soluble polypeptide with molecular weight of approximately 23 kDa (the 23-kDa polypeptide) was identified in the lens of common frog Rana temporaria L. According to the gel filtration data, the peptide is a part of an oligomeric protein with molecular weight of more than 300 kDa (alpha-crystallin fraction). A highly pure fraction of the 23-kDa polypeptide was isolated by two-step ion-exchange chromatography and SDS electrophoresis and the specific antibodies were obtained. Immunohistochemistry showed the presence of the 23-kDa polypeptide in the cytoplasm of lens epithelial cells (including its central region) and in the zones neighbouring the plasma membranes in cortical fibers. The 23-kDa polypeptide was not found in the lens central zone (nucleus). It was also present in the retina (in the cells of inner nuclear layers), but not in the other tissues and organs of adult frog. Immunochemical analysis showed that the 23-kDa polypeptide was different from all known crystallins of frogs and other animals (bull, mouse, rat, and chicken). The nature of the 23-kDa polypeptide and the relation of its expression with lens cell differentiation are discussed.     

The synthesis and localization of crystallins in different cell compartments of the crystalline lens in adult frogs: immunoautoradiographic and immunofluorescent research

The purpose of this study was to analyze immunochemically the synthesis and distribution of tissue-specific proteins, i.e., alpha-, beta- gamma- and rho-crystallins, in morphologically distinct regions of the frog (Rana temporaria L.) lens which consist of cells at various stages of differentiation, maturation and aging. Five such cell compartments can be distinguished in the lens: (1) central zone of lens epithelium (stem/clonogenic cells); (2) equatorial epithelial cells (differentiating cells); (3) lens fibers of the outer cortex (post-mitotic differentiated cells); (4) lens fibers of the deep cortex (cells without nuclei at terminal stage of differentiation); and (5) cells of the lens "nucleus" (cells formed during embryogenesis). Intact lenses and isolated lens epithelium were cultured in vitro in the presence of 35S-methionine. Then lens epithelium, outer and deep cortex, and lens nucleus were extracted with buffered saline and extracts used for immunoautoradiography. Distribution of crystallins in paraffin sections of the whole lens or isolated lens epithelium was studied using indirect immunofluorescence. Synthesis of alpha-crystallins was observed in lens epithelium and cortex, but not in lens nucleus. According to immunohistochemistry, these proteins were absent from central part of the lens epithelium: positive fluorescence was observed only in elongating cells at its periphery and in lens fibers. The data on beta-crystallins are similar except that synthesis of these proteins (traces) was detected also in lens nucleus. Synthesis of gamma-crystallins was detected in lens cortex and nucleus (traces) but not in epithelium. Immunohistochemistry showed that these proteins are absent from all regions of lens epithelium and found only in fiber cells of cortex and nucleus. Rho-crystallin was synthesized in all cell compartments of the adult lens, and all lens cells contained this protein. Our results show that cells of central lens epithelium do not contain alpha- beta- or gamma-crystallins (or the rate of their synthesis is insignificant). While cells are moving towards lens equator and elongating, synthesis of alpha- and beta-crystallins is activated. Gamma-crystallins are synthesized later, first in young lens fibers near lens equator. During embryonic development in amphibia, in contrast, gamma- and beta-crystallins are detected at earlier stages than alpha- and rho-crystallins (Mikha?lov et al., 1988). These data suggest that different mechanisms are involved in differentiation on lens fibers from embryonic precursor cells, on one hand, and from epithelial stem cells of adult lens, on the other.     

Collagen synthesis by long-lived mRNA in embryonic chicken lens

Lens capsule collagen synthesis by epithelial and fiber cells was examined by immunoprecipitation and collagenase digestion in embryonic and posthatch chicken eye lens. Epithelial cells and lens fibers in the process of terminal differentiation produce alpha 1 and alpha 2 type IV collagen chains. At 6 days of embryonic development in addition to the alpha 1 (IV) and alpha 2 (IV) collagen chains, lens cells produce high molecular weight collagenase-sensitive proteins not immunologically related to type IV collagen. Lens capsule collagen components have been identified in central and outer fibers isolated from 18-day embryos and from 10-day posthatch chicken eyes. At these stages, fibers which have an increasing number of picnotic nuclei still show collagen synthesis due to long-lived mRNA. Analysis of collagen synthesis by lens cells incubated with actinomycin D suggests that stabilization of collagen mRNA occurs in lens fiber cells and to a lesser extent in epithelial cells as early as 6 days of embryonic development.     

Jagged 1 is necessary for normal mouse lens formation

In mammals, two spatially and temporally distinct waves of fiber cell differentiation are crucial steps for normal lens development. In between these phases, an anterior growth zone forms in which progenitor cells migrate circumferentially, terminally exit the cell cycle and initiate differentiation at the lens equator. Much remains unknown about the molecular pathways orchestrating these processes. Previously, the Notch signal transduction pathway was shown to be critical for anterior lens progenitor cell growth and differentiation. However, the ligand or ligand(s) that direct these events are unknown. Using conditional gene targeting, we show that Jagged1 is required for lens fiber cell genesis, particularly that of secondary fiber cells. In the absence of Jagged1, the anterior growth and equatorial transition zones fail to develop fully, with only a handful of differentiated fiber cells present at birth. Adult Jagged1 conditional mutants completely lack lenses, along with severe anterior chamber deformities. Our data support the hypothesis that Jagged1-Notch signaling conveys a lateral inductive signal, which is indispensable for lens progenitor cell proliferation and differentiation.     

Cell population kinetics of the mouse lens epithelium

The dividing lens epithelium of 8-week-old CF1 mice consists of a monocellular layer of about 31,000 cells and does not include the postmitotic cells of the meridional rows and another postmitotic zone of seven cell positions' width immediately anterior to the rows. The latter two populations contain approximately 3,600 and 9,000 cells, respectively, for a total of 44,000 cells in the entire lens epithelium. Autoradiographic analysis based upon mitotic index and cell cycle times indicates that the epithelium produces 207 new lens fibers a day. Throughout the 20-day period of study, labeled cells appeared almost entirely as pairs following a single dose of ³H-thymidine and clusters of labeled nuclei were not seen. Moreover, the number of labeled cells dropped only slowly with time, as did the grain counts. These observations indicate that logarithmic division “cascade” does not occur in the lens. The dividing cell population consists largely of a slowly cycling stem cell group, dividing once about every 17–20 days, and consisting of some 5,000 cells. A subpopulation may exist which undergoes two rapid consecutive divisions before becoming postmitotic, but this is too small to make a significant contribution to lens fiber production. Four days are required to transit the postmitotic zone, and an additional 43 or so are needed to transit the meridional rows and differentiate into anucleate lens fibers. Data from other laboratories indicate that the entire process, from mitosis to final differentiation, requires about 4 months. Hence, most of this time is spent in migration of nondividing cells.     

The expression of differentiation by chicken lens epithelium in in vitro cell culture

Dissociated cells of the lens epithelium of newly hatched chickens were cultured in vitro to investigate whether cells actively grown in culture retain their own differentive entiative traits to form lens fibers. After an exponential growth phase of the flattened epithelial cells, a number of “islets” of smaller epithelial cells with polygonal shape appeared. Along the periphery of these islets, the characteristic morphological change which leads to the formation of spherical bodies was observed. Electron microscopic observation showed the differentiation of lens fibers in these spherical bodies comparable to those in the lens in situ. Accumulation of δ-chrystallin was confirmed in such “lentoid” bodies. Outgrowth of the lens epithelial cells was maintained in in vitro culture up to about 50 days with several subculturings. The formation of lentoid bodies occurred in each subculture generation, which started from a homogeneous population of flattened epithelial cells. The present culture conditions permit the maintenance of such a population of cells that have a high growth potential and stably retains their differentiative trait to form lens fiber, even after repeated replication under in vitro conditions.     

The retention of differentiated properties by lens epithelial cells in clonal cell culture

A small number of cells of lens epithelium from newly hatched chickens were cultured at clonal density to investigate the retention of differentiated properties during cellular growth in vitro. Singly plated cells proliferated to produce colonies, at least some of which were considered to be true clones of single cell origin. The differentiation of lens fibers occurring in many colonies was identified through observations by electron microscopy as well as immunofluorescence utilizing specific antiserum against lens fibers. Primary or secondary mass cultures of cells of lens epithelium contained cells which produce differentiated colonies when cultured at clonal density. Colony-producing cells can be differentially dissociated from monolayers by EDTA treatment without using tyrpsin. For successful culture of cells of lens epithelium at clonal density, the use of conditioned medium is necessary.     

Misexpression of IGF-I in the mouse lens expands the transitional zone and perturbs lens polarization

Insulin-like growth factor-I (IGF-I) has been implicated as a regulator of lens development. Experiments performed in the chick have indicated that IGF-I can stimulate lens fiber cell differentiation and may be involved in controlling lens polarization. To assess IGF-I activity on mammalian lens cells in vivo, we generated transgenic mice in which this factor was overexpressed from the alphaA-crystallin promoter. Interestingly, we observed no premature differentiation of lens epithelial cells. The pattern of lens polarization was perturbed, with an apparent expansion of the epithelial compartment towards the posterior lens pole. The distribution of immunoreactivity for MIP26 and p57(KIP2) and a modified pattern of proliferation suggested that this morphological change was best described as an expansion of the germinative and transitional zones. The expression of IGF-I signaling components in the normal transitional zone and expansion of the transitional zone in the transgenic lens both suggest that endogenous IGF-I may provide a spatial cue that helps to control the normal location of this domain.     

ATTACHMENT OF RIBOSOMES TO MEMBRANES DURING POLYSOME FORMATION IN MOUSE SARCOMA 180 CELLS

Addition of nutrients to starved mouse S-180 cells leads to rapid conversion of ribosomal monomers to polysomes. During this process, a portion of the ribosomes originally found in the 17,000 g (10 min centrifugation) supernatant of cell lysates becomes firmly attached to structures sedimenting at 500 g (5 min centrifugation). Electron microscopy of sections of the intact cells showed the change from randomly distributed ribosomal particles to clusters. Association with membranes also became evident. The material sedimenting at 500 g comprised nuclei enclosed in an extensive endoplasmic reticulum (ER) network. This fraction prepared from recovering cells showed numerous ribosome clusters associated with the ER network. The appearance of many of these clusters indicated that the ribosomal particles were not directly bound to the membranes. RNase treatment released about 40% of the attached ribosomes as monomers, and ethylenediaminetetraacetic acid released 60% as subunits. It is suggested that during polysome formation a portion of the ribosomes becomes attached to the membranes through the intermediary of messenger RNA.     

Decreased turnover of phosphatidylinositol accompanies in vitro differentiation of embryonic chicken lens epithelial cells into lens fibers

The in vivo differentiation of embryonic chicken lens epithelial cells into lens fibers is accompanied by a marked decrease in the rate of degradation of phosphatidylinositol. The present experiments were undertaken to determine whether a similar change in phosphatidylinositol metabolism occurs during in vitro lens fiber formation in cultured explants of embryonic chicken lens epithelia. Lens epithelial cells in the explants differentiate into lens fibers following the addition of fetal calf serum, insulin or chicken vitreous humor to the culture medium. The results show that phosphatidylinositol is degraded with a half-life of 3-6 h in cultured lens epithelia that are not stimulated to differentiate. In contrast, no degradation occurs for at least 6 h in lens epithelia stimulated to form lens fibers. The stabilization of phosphatidylinositol is apparent within 4 h after the onset of fiber cell formation, and thus represents an early event in differentiation. The rapid degradation of phosphatidylinositol in lens epithelia is accompanied by comparably rapid synthesis. During this metabolic turnover only the phosphorylinositol portion of the molecule is renewed, as expected if hydrolysis occurs by the action of a phospholipase C, such as phosphatidylinositol phosphodiesterase. Thus, these data suggest that agents which produce in vitro differentiation of embryonic chicken lens epithelial cells into lens fibers lead to a reduction in either the amount or the activity of phospholipase C.     

Increased sensitivity of various genes to endogenous DNase activity in terminal differentiating chick lens fibers

In the lens, epithelial cells from the equatorial zone differentiate into postmitotic elongated fibers. One aspect of this differentiation is nuclear shape transformation and DNA degradation. This process is controlled by DNase activity which in fiber nuclei increases with development. DNase activity is also present in the epithelial cell nuclei which appears to be non-functional but could be activated in vitro by exogenous addition of Ca2+. We have analyzed the possible selective action of endogenous DNase on 3 genes involved in lens terminal differentiation, namely delta-crystallin, beta-tubulin and vimentin, and on 1 gene not thought to participate in this process, ovalbumin. We have compared restriction DNA patterns of these genes in nuclei isolated from 11-day-old chick embryos and incubated in Ca2+-free medium or in fresh epithelial and fiber lens tissue at 11 and 18 days of development. During incubation in vitro of 11-day fiber nuclei, there is a net increase in the sensitivity of the delta-crystallin, beta-tubulin, ovalbumin and vimentin chromatin to the endogenous DNase. The vimentin gene appears to be more stable than the beta-tubulin and delta-crystallin genes indicating a degree of specificity of the endogenous DNase activity. In the epithelial nuclei, the lens-specific genes appear to be more stable but paradoxically there is a net degradation of the ovalbumin gene. In freshly isolated tissues the 4 genes were detected in epithelial and fiber cells at 11 and 18 days. Furthermore, in the mature fibers in which the nuclei were degenerating, the latter genes were still not completely digested.     

Ribosomal RNA cistron number in a polyploid series of plants

A comparison has been made of the amount of DNA coding for ribosomal RNA present in a polyploid series of plants of Datura innoxia. The plants which were produced by in vitro culture of pollen grains were haploid, diploid, triploid, tetraploid and hexaploid. In all instances there was a similar proportion of DNA coding for ribosomal RNA. The implications of these results are discussed, and the data compared with that available from other series of plants of different DNA content or ploidy.     

Degradation of nuclear DNA by DNase II-like acid DNase in cortical fiber cells of mouse eye lens

The eye lens is composed of fiber cells that differentiate from epithelial cells on its anterior surface. In concert with this differentiation, a set of proteins essential for lens function is synthesized, and the cellular organelles are degraded. DNase II-like acid DNase, also called DNase IIbeta, is specifically expressed in the lens, and degrades the DNA in the lens fiber cells. Here we report that DNase II-like acid DNase is synthesized as a precursor with a signal sequence, and is localized to lysosomes. DNase II-like acid DNase mRNA was found in cortical fiber cells but not epithelial cells, indicating that its expression is induced during the differentiation of epithelial cells into fiber cells. Immunohistochemical and immunocytochemical analyses indicated that DNase II-like acid DNase was colocalized with Lamp-1 in the lysosomes of fiber cells in a relatively narrow region bordering the organelle-free zone, and was often found in degenerating nuclei. A comparison by microarray analysis of the gene expression profiles between epithelial and cortical fiber cells of young mouse lens indicated that some genes for lysosomal enzymes (cathepsins and lipases) were strongly expressed in the fiber cells. These results suggest that the lysosomal system plays a role in the degradation of cellular organelles during lens cell differentiation.     

Identification and differentiation of lens cells in tissue culture]

The cells of S-phase labelled prior to cultivation with H3-thymidine and other neighbouring cambial cells of the lens of the pig, cattle and sheep were found to form morphologically underdifferentiated zones of growth. The zones of growth were formed in the culture from differentiating in vivo cells of the lens. The cells of these zones occasionally resembled abortively differentiated lens fibres in vivo. The growth zones of the lens cells in vitro are comparable by its growings in trauma or cataract in vivo. In lens cultures under routine conditions of cultivation there occurs disturbance of normal embryonic histogenesis and abortive differentiation of the already differentiated in vivo cells.     

alpha6 Integrin is regulated with lens cell differentiation by linkage to the cytoskeleton and isoform switching.

The developing chicken embryo lens provides a unique model for examining the relationship between alpha6 integrin expression and cell differentiation, since multiple stages of differentiation are expressed concurrently at one stage of development. We demonstrate that alpha6 integrin is likely to mediate the inductive effects of laminin on lens differentiation as well as to function in a matrix-independent manner along the cell-cell interfaces of the differentiating cortical lens fiber cells. Both alpha6 isoform expression and its linkage to the cytoskeleton were regulated in a differentiation-specific manner. The association of alpha6 integrin with the Triton-insoluble cytoskeleton increased as the lens cells differentiated, reaching its highest levels in the cortical fiber region where the lens fiber cells are formed. In this region of the lens alpha6 integrin was uniquely localized along the cell-cell borders of the differentiating fiber cells, similar to beta1. alpha6beta4, the primary transmembrane protein of hemidesmosomes, is also expressed in the lens, but in the absence of hemidesmosomes. Differential expression of alpha6A and alpha6B isoforms with lens cell differentiation was seen at both the mRNA and the protein levels. RT-PCR studies demonstrated that alpha6B was the predominant isoform expressed both early in development, embryonic day 4, and in the epithelial regions of the day 10 embryonic lens. Isoform switching, with alpha6A now the predominant isoform, occurred in the fiber cell zones. Immunoprecipitation studies showed that alpha6B, which is characteristic of undifferentiated cells, was expressed by the lens epithelial cells but was dramatically reduced in the lens fiber zones. Expression of alpha6B began to drop as the cells initiated their differentiation and then dropped precipitously in the cortical fiber zone. In contrast, expression of the alpha6A isoform remained high until the cells became terminally differentiated. alpha6A was the predominant isoform expressed in the cortical fiber region. The down-regulation of alpha6B relative to alpha6A provides a developmental switch in the process of lens fiber cell differentiation.     

The 23 kDa Polypeptide from Common Frog Lens: Isolation,Properties, and Cellular Localization

The major water-soluble polypeptide with molecular weight of approximately 23 kDa (the 23 kDa polypeptide) was identified in the lens of common frog Rana temporaria L. According to the gel filtration data, the peptide is a part of an oligomeric protein with molecular weight over than 300 kDa (-crystallin fraction). A highly pure fraction of the 23 kDa polypeptide was isolated by two-step ion-exchange chromatography and SDS electrophoresis and the specific antibodies were obtained. Immunohistochemistry showed the presence of the 23 kDa polypeptide in the cytoplasm of lens epithelial cells (including its central region) and in the zones neighboring the plasma membranes in the cortical fibers. The 23 kDa polypeptide was not found in the lens central zone (nucleus). It was also present in the retina (in the cells of inner nuclear layers), but not in the other tissues and organs of adult frog. Immunochemical analysis showed that the 23 kDa polypeptide was different from all known crystallins of frogs and other animals (bull, mouse, rat, and chicken). The nature of the 23 kDa polypeptide and the relation of its expression with the lens cell differentiation are discussed.     

Delta-crystallin mRNA in chick lens cells: mRNA accumulates during differential stimulation of delta-crystallin synthesis in cultured cells.

Increasing specialization for δ-crystallin synthesis is a prominent feature of the differentiation of chick lens epithelial cells into lens fiber cells and can be studied in cultured embryonic lens epithelia. Quantitation of δ-crystallin mRNA by molecular hybridizaton to a [³H]DNA complementary to δ-crystallin mRNA demonstrates that differentiation, both in ovo and in tissue culture, is associated with the accumulation of δ-crystallin mRNA. In the cultures, there is an overall stimulation of protein synthesis, including δ-crystallin mRNA during the first 5 hr in vitro. Between 5 and 24 hr in vitro there is a differential stimulation of δ-crystallin synthesis and an accumulation of δ-crystallin mRNA that can quantitatively account for this stimulation.     

Hydroxylation of dehydroepiandrosterone in the eye lens.

Hydroxylation of the steroid hormone dehydroepiandrosterone in the calf lens is inhibited by carbon monoxide and stimulated by NADPH. The enzyme concerned was found to be membrane-bound. Although the enzyme resembles the liver mono-oxygenase system in these characteristics, the presence of cytochrome P-450 in the lens could not be proved by measuring a difference spectrum with carbon monoxide, probably because the concentration of the enzyme is too low. Preparations of purified lens fiber plasma membranes also hydroxylate dehydroepiandrosterone. This indicates that the fiber plasma membranes act as supports for enzyme complexes. In this respect they resemble cytoplasmic membranes and plasma membranes derived from other tissues. Cultured lens cell contain the hydroxylating enzyme, although its activity is dependent on the culture conditions used. It is striking that in lens fibers the enzyme which seems to convert dehydroepiandrosterone specifically occurs on the plasma membranes, whereas, for instance, in liver, hemoproteins localized on the endoplasmic reticulum, exert hydroxylation activity towards a variety of steroids. This suggests some regulatory role for dehydroepiandrosterone in lens growth and metabolism.