Adrenergic stimulation of lens cytoskeletal phosphorylation

Stimulation of lens fiber cytoskeletal phosphorylation by adrenergic drugs is described. The effect of isoproterenol on phosphorylation of the 47 Kd beaded filament protein is dose-dependent, detectable as soon as one minute after treatment and blocked by propranolol. Epinephrine increases the phosphorylation of both 47 Kd and the intermediate filament protein, vimentin. 47 Kd phosphorylation is also increased by norepinephrine, dibutyryl-cAMP or forskolin. The results indicate that lens fiber cytoskeletal phosphorylation is regulated, at least in part, via a beta-adrenergic receptor coupled to cyclic AMP production.     

Development- and differentiation-dependent reorganization of intermediate filaments in fiber cells

PURPOSE. To define the remodeling of lens fiber cell intermediate filaments (IF) that occurs with both development and differentiation. METHODS. Prenatal and postnatal mice were probed for the IF proteins phakosin, filensin, and vimentin, using light microscope immunocytochemical methodology. RESULTS. The pattern of vimentin accumulation in elongating fiber cells changed with development. Early in development vimentin first emerged predominantly as focal accumulations in the basal region of both epithelial and primary fiber cells. A light diffuse cytoplasmic staining was also noted. Later in embryonic development, and through maturity, vimentin in fiber cells was predominantly associated with the plasma membrane with no anterior-posterior polarity. Phakosin and filensin were first detected in the very latest stages of primary fiber elongation and continued to accumulate well after cells had completed elongation. Initially, these proteins accumulated in the anterior half of the fiber cells and were cytoplasmic in distribution. After P13, the pattern of initial distribution in differentiating fiber cells changed to a predominantly plasma membrane localization. Neither beaded filament protein showed focal basal accumulations. In mature lenses, all three proteins ultimately disappeared from the nuclear fiber cells. CONCLUSIONS. Beaded filament protein accumulation lags significantly behind both primary and secondary fiber cell elongation, suggesting a functional role subsequent to elongation. The subcellular distribution of vimentin and the beaded filament proteins showed marked differences within the cell, with differentiation, and with development. The differences in time of initial synthesis and in distribution of these IF proteins may bear on hypotheses about the role of IFs in fiber cell elongation and in structural-functional polarity of the fiber cell.     

Resisting the effects of aging: a function for the fiber cell beaded filament

PURPOSE: The beaded filament is a cytoskeletal structure that has been found only in the lens fiber cell. It includes phakosin and filensin, two divergent members of the intermediate filament family of proteins that are also unique to the fiber cell. The authors sought to determine what function the beaded filament fulfills in the lens. METHODS: Light microscopy and electron microscopy were used to characterize structural changes that occurred in previously generated phakosin and filensin knockout mice. Immunocytochemistry and electron microscopy were used to define the distribution of phakosin, filensin, and beaded filaments. RESULTS: In phakosin and filensin knockout mice, initial lens development and the early phases of fiber cell differentiation proceed in a manner largely indistinguishable from that of wild type. Fiber cells elongate, undergo organelle elimination, and, in the organelle-free zone, develop the unique paddlelike extensions that characterize cells in this region. Subsequent to those stages, however, fiber cells undergo loss of the differentiated fiber cell phenotype and loss of the long-range stacking that characterizes fiber cells and that has been considered essential for clarity. CONCLUSIONS: The beaded filament is not required for the generation of the differentiated fiber cell phenotype but is required to maintain that differentiated state and the long range order that characterizes the lens at the tissue level.     

Differentiation of chick lens epithelial cells: involvement of the epidermal growth factor receptor and endogenous ligand

PURPOSE: To characterize the constitutively activated epidermal growth factor receptor in a lens epithelial cell population experiencing initial stages of lens fiber formation, the chick lens annular pad. METHODS: Phosphotyrosine levels of the receptor were examined with western blot analysis and immunoprecipitation after ligand stimulation. Endogenous receptor ligands were immunologically identified in whole cell lysates of freshly isolated cells. The expression of lens fiber-specific differentiation marker proteins was examined with western blot analysis and enzyme-linked immunosorbent assay (ELISA) in short-term primary cultures of annular pad cells exposed to ligand. RESULTS: The major phosphotyrosine-containing protein in annular pad cells comigrated with the epidermal growth factor receptor and increased its phosphotyrosine content after epidermal growth factor treatment. Both time- and dose-dependent responses were noted. The constitutive activation of the receptor was determined in the presence of phosphatase inhibitors. Endogenous transforming growth factor-alpha, but not epidermal growth factor, was detected in freshly isolated cells. Transforming growth factor-alpha (TGF-alpha) treatment produced greater increases in receptor phosphotyrosine levels than equimolar levels of epidermal growth factor. Finally, TGF-alpha treatment induced increased expression of the beaded filament protein filensin when compared with control cells. Filensin expression was increased further when cells were costimulated with TGF-alpha and cAMP analogs. CONCLUSIONS: At least in the postnatal lens, endogenous TGF-alpha may affect overall growth patterns by modulating differentiation-specific protein expression. Furthermore, signaling pathways elicited by TGF-alpha and cAMP analogs converge to cooperatively enhance lens fiber differentiation.     

Lens intermediate filaments

The ocular lens assembles two separate intermediate filament systems sequentially with differentiation. Canonical 8-11 nm IFs composed of Vimentin are assembled in lens epithelial cells and younger fiber cells, while the fiber cell-specific beaded filaments are switched on as fiber cell elongation initiates. Some of the key features of both filament systems are reviewed.     

Immunologic conservation of the fiber cell beaded filament

Lenses were obtained from the eyes of four different classes of Chordates, including Mammalia (rat, mouse, cow, human), Aves (chicken), Amphibia (tiger salamander), and Osteichthyes (steelhead), as well as from one Mollusca (squid). Buffer soluble, urea soluble and urea insoluble fractions were prepared from each, and probed by western blot analysis for the presence of the lens fiber cell 115 and 49 kD beaded filament proteins. Application of both polyclonal and monoclonal antibodies revealed that an immunologic homologue to the bovine fiber cell 115 kD protein is present in all examples of Chordates tested, and that this homologue possessed properties very similar to those of its bovine counterpart. Both monoclonal and polyclonal antibodies revealed an immunologically cross-reactive homologue in squid as well, but suggested that the squid protein had a native molecular weight of closer to 70-80 kD. A monoclonal antibody to the bovine 49 kD beaded filament protein was successful at identifying an immunologic homologue to this protein in mouse, chicken, and tiger salamander. Ultrastructural analysis of rat, human, and fish lenses showed that a beaded filament was present in these lenses, which was indistinguishable from that seen in the bovine lens. In the squid a filamentous, beaded structure was observed, but it differed from that seen in the bovine lens. We conclude from the data presented that the beaded filament, and its constituent proteins, are well-conserved. This data should facilitate the identification of lens cytoskeletal proteins and structure in a wide range of animal models, and establish that probes for these proteins may be of broad applicability.     

Characterization of a mutation in the lens-specific CP49 in the 129 strain of mouse

PURPOSE: The 129 strain of mouse carries a mutation in the gene for CP49 (phakinin), an intermediate filament protein thus far demonstrated only in the lens fiber cell. As such, these mice represent naturally occurring mutants of interest in the study of the lens cytoskeleton. However, this strain of mouse is also widely used as a source of embryonic stem cells in gene-targeting studies. The presence of a mutation in a lens-specific gene can confound interpretation of studies in which lens genes have been knocked out. In the present study, both the genotype and phenotype of these mice were characterized, to permit an evaluation of the biological impact of this mutation and to facilitate the discrimination between wild-type and mutant animals that have been derived from this strain in gene-targeting studies. METHODS: The CP49 cDNA and, when relevant, the genomic DNA sequences were determined for the 129/SvJ and C57BL/6J mice and from a commercially available 129/OLa P1 genomic clone. PCR primers were screened for their capacity to discriminate between the mutant and wild-type CP49 genes. Northern blot analysis was used to assess mRNA levels for CP49, filensin, and gammaS-crystallin (control). Western blot analysis was used to identify changes in protein size and abundance. The impact of the mutation on lens architecture was evaluated at the light-microscope level. Lens fiber cell ghosts from mutant and wild-type mice were examined in the electron microscope for the presence of beaded filaments. Lens clarity was assessed by slit lamp. RESULTS: The 129 strain of mice exhibited a 6303-bp deletion from the end of intron B, and the beginning of exon 2. This deletion results in the loss of the exon 2 splice acceptor site, absence of exon 2 from the CP49 mRNA, and dramatically reduced levels of CP49 mRNA. The CP49 protein was undetectable by Western blot analysis. Messenger RNA levels for filensin, CP49's assembly partner, were normal, but protein levels were sharply reduced. Light microscopy established that the initial differentiation and elongation of the fiber cells proceeded normally. Electron microscopy showed the absence of beaded filaments, whereas slit lamp microscopy showed a slowly emerging and progressive loss of optical clarity. CONCLUSIONS: The 129/SvJ and 129/OLa strains of mice harbor a mutation that sharply reduces CP49 mRNA levels and essentially eliminates both CP49 and the beaded filament. These lenses exhibited a slow but progressive loss of optical clarity with age. Thus, the 129 strain of mouse behaves as a functional CP49 knockout. The loss of clarity in the lenses of these animals and the absence of beaded filaments (and any attendant interactions that may exist between beaded filaments and other lens proteins/structures) suggest that gene-targeting studies of lens proteins in which the 129 strain was used as a source of embryonic stem cells may need reevaluation.     

The Mr 115 kd fiber cell-specific protein is a component of the lens cytoskeleton

Electron microscope level immunocytochemistry was used to localize a lens fiber cell-specific protein with an Mr of 115 kd. Affinity-purified polyclonal antibodies were utilized on sections of detergent-extracted, acrylic-embedded lens cortical fiber cells. Monoclonal antibodies were utilized for pre-embeddment labelling of a subcellular fraction of lens fiber cells generated by homogenization, and high-speed centrifugation. The results indicate that the Mr 115 kd antigen is a component of the lens fiber cell cytoskeleton, specifically the beaded filament (BF), a cytoskeletal element thought to be unique to the differentiated lens fiber cell.     

Phosphatidylinositol 3-kinase is necessary for lens fiber cell differentiation and survival

PURPOSE: To determine the mechanisms of action of phosphatidylinositol 3-kinase (PI3K) in lens cell differentiation and survival. METHODS: Primary quail lens cell cultures were treated at different stages of differentiation with the PI3K inhibitor LY294002, and expression of survival proteins and differentiation markers were determined by immunoblot analysis. The connection between PI3K regulation of lens differentiation and actin cytoskeleton reorganization was examined by fluorescent-phalloidin staining and Rac activity assay. Survival in the absence of PI3K signaling was examined by TUNEL and DAPI staining. Phosphorylation of the PI3K effector glycogen synthase kinase-3 (GSK3) in the absence of PI3K signaling was induced with lithium chloride. RESULTS: Exposure to LY294002 blocked lens epithelial cell differentiation initiation. This result was linked to attenuation of Rac activity and inhibition of actin filament reorganization from stress fibers to cortical fibers, which has been shown to signal lens differentiation initiation. The survival of lens epithelial cells in the absence of PI3K signaling correlated with induction of numerous survival factors, including Bcl-2. In contrast, inhibition of PI3K signaling in differentiating lens fiber cells induced apoptosis by blocking inactivation of GSK3, showing that PI3K/GSK3 signaling has a protective role in the late stages of differentiation as nuclei and organelles are lost. CONCLUSIONS: PI3K signaling regulates lens cell differentiation initiation through its ability to signal reorganization of the actin cytoskeleton from stress fibers to cortical fibers. In differentiating lens fiber cells, PI3K has a protective function, signaling survival through inactivation of its downstream effector GSK3.     

Lens actin: purification and localization

Actin was purified from the chick lens using DEAE-52 column chromatography followed by hydroxylapatite chromatography. The antibody produced against the purified actin cross-reacted specifically with lens actin from other species in addition to smooth and skeletal muscle actin and labelled the stress bundles of cultured fibroblasts. Actin was localized, using immunological methods, primarily to the plasma membrane of the epithelial and fiber cells of the chick and human lens. Actin filaments were also identified by HMM S-1 labeling in bovine cortical fiber cells. Using this procedure, the actin filaments were found throughout the fiber cell but were mainly concentrated near the plasma membrane and in cell processes. They formed a population distinct from the beaded filaments. The initial DEAE-52 column chromatography was also useful in the initial purification of lens fiber cell intermediate filament protein and two species of beta-crystallins.     

Evaluation of fibroblast growth factor signaling during lens fiber cell differentiation

PURPOSE: Previous studies have implicated members of the fibroblast growth factor (FGF) and insulin-like growth factor (IGF) families as stimulators of lens fiber cell differentiation in rodent and chicken embryo lenses, respectively. In the present study, the role of FGFs in fiber cell differentiation and epithelial cell proliferation in chicken embryos was examined. METHODS: Lenses were injected on embryonic day (E)3 with replication-defective retroviruses that express full-length or truncated FGF receptor (FGFR)-1 or a secreted form of FGF1. Lens epithelial explants were cultured in defined medium or medium supplemented with FGFs or vitreous humor, in the presence or absence of the FGF receptor antagonist SU5402. Explants were also cultured in vitreous humor that had been depleted of heparin-binding growth factors. Cell elongation was measured optically and protein accumulation by densitometry and Western blot analysis. RESULTS: Lens fiber cell differentiation was not inhibited in cells infected with virus expressing truncated FGFR1. Epithelial cells infected with virus encoding a secreted form of FGF1 did not differentiate into ectopic fiber cells. Viral transduction of FGFR1, truncated FGFR1, or FGF1 did not appreciably alter the proliferation of lens epithelial cells. Bovine vitreous humor stimulated chicken embryo lens epithelial cells to elongate and express markers of lens fiber cell differentiation. Bovine vitreous humor, but not FGF2, protected lens epithelial cells from apoptosis. Depleting vitreous humor of heparin-binding growth factors or treatment of lens cells with SU5402 did not inhibit the initial, rapid phase of lens cell elongation. Both treatments, used separately or together, reduced but did not prevent the expression of later markers of fiber cell differentiation. CONCLUSIONS: Fiber differentiation factors that are not members of the FGF family are present in chicken and mammalian vitreous humor. The factors that stimulate fiber cell differentiation in avian and mammalian eyes are similar.     

Expression and distribution of cytoskeletal IFAP-300kD as an index of lens cell differentiation.

By their implication in the organization of the intermediate filament (IF) cytoskeleton, IF-associated proteins (IFAPs) can delineate subsets of the same IF type within a cell; moreover, they are proving useful as markers of the differentiation states of certain cells. For these reasons the expression of the vimentin-associated IFAP-300kD was investigated in the constantly differentiating cell lineage of the adult bovine lens. Immunofluorescence microscopy and immunoblot analysis were employed using a monoclonal anti-IFAP-300kD and a rabbit anti-lens vimentin. Cultures of adult lens epithelial cells were immunopositive for the IFAP. By double-label studies the IFAP-300kD pattern co-localized with that of the vimentin-type IF; moreover, the IFAP pattern co-distributed with that of both colchicine-sensitive and -insensitive IF systems. IFAP-300kD was also present in a co-distributing pattern with vimentin IF in fresh lens epithelial cells on whole mounts. There was a differential expression of the IFAP in the lens fiber cells in that those of the cortex exhibited the IFAP and vimentin IF, while both proteins were absent from the nuclear fiber cells. Furthermore, there was a differential distribution of the IFAP within the cortical fiber cells in that the IFAP localized only with a paramembranal subset of IF. Immunoblot analysis supported the presence of IFAP-300kD in the lens cytoskeletal fraction. IFAP-300kD thus identified a subset of vimentin IF whose location may have functional significance for the cortical fiber cell. The changes in the IFAP's expression and distribution pattern throughout lens cell differentiation in the adult organ suggest the usefulness of IFAP-300kD as a potential marker in studying lens cell differentiation in vitro.     

The age of rats affects the response of lens epithelial explants to fibroblast growth factor. An ultrastructural analysis.

Fibroblast growth factor (FGF) is a potent inducer of fiber differentiation in lens epithelial explants from neonatal rats as assessed by the accumulation of fiber-specific proteins (beta- and gamma-crystallins) and the progression of cells through a sequence of morphologic events characteristic of fiber differentiation in situ. Because new fibers normally are formed in the lens throughout life, the authors questioned whether epithelial cells from rats of all ages are induced to differentiate into fibers by FGF. Earlier studies have shown that, with the increasing age of the donor rat, the lens epithelial explants had a reduced ability to accumulate beta- and gamma-crystallins in response to FGF. To determine if the characteristic morphologic events in fiber differentiation were induced by FGF in explants from rats of different ages, an ultrastructural study was done. Using the time of appearance and level of expression of the following morphologic markers of fiber differentiation: (1) cell elongation, (2) reduction of cytoplasmic organelles, (3) formation of cell processes, and (4) fiber denucleation, the level of fiber differentiation induced by FGF was assessed in explants from 10-, 21-, 100-, and 175-day-old rats. These results showed that, with increasing donor age, epithelial cells showed a gradual decline in responsiveness to FGF. This was manifested by a slower progression through the sequence of fiber-specific structural events as the age of the donor rat increased. At all ages studied, cells in the central region of explants responded more slowly than cells from the peripheral region. The finding that FGF induces events in fiber differentiation, albeit at a slower rate, in explants from mature rats supports the hypothesis that FGF in the eye continues to play a role in inducing lens epithelial cells at the lens equator to differentiate into fibers throughout life.     

In vitro generation of functional lens-like structures with relevance to age-related nuclear cataract

PURPOSE: To investigate the capacity of lens epithelial cells, maintained in a modified explant culture system, to mimic normal patterns of lens cell differentiation and to regenerate lens structure and function. METHODS: Lens epithelial explants were set up in pairs with their apical surfaces facing each other. These explant pairs (EPs) were then cultured in vitreous for up to 43 days to promote their growth and differentiation. Immunohistochemistry and conventional light and electron microscopy were used to assess structural and functional properties of the lens-like structures that developed from EPs. RESULTS: EPs that were asymmetrically exposed to vitreous routinely produced biconvex, lens-like structures composed of ordered epithelial and fiber cells that were transparent and had some focusing and magnifying ability. In addition, characteristic of the lens in vivo, fiberlike cells that were peripherally situated in EPs contained markers of the relatively early stages of fiber differentiation, whereas centrally situated cells contained markers of terminally differentiated fibers. During long-term culture of the EPs, a central opacity appeared that had structural features similar to those reported for the early stages of human, age-related nuclear cataract. CONCLUSIONS: This study shows that, given appropriate culture conditions, lens epithelial cells can regenerate ordered lens-like structures with functional properties. This system represents a valuable new tool for the investigation of factors involved in the generation of normal lens structure and function and lens opacification.     

Differential protein expression in lens epithelial whole-mounts and lens epithelial cell cultures

PURPOSE: Lens fibergenesis is a problem in several types of cataract and in the posterior capsular opacification following cataract surgery. To correct improper fiber differentiation or to prevent unwanted growth on the posterior capsule following cataract surgery requires a thorough understanding of normal and abnormal fiber formation. To this end, studies were initiated to characterize fiber differentiation in the bovine lens and in lens epithelial cell cultures. METHODS: Indirect immunofluorescence and immunoblot analysis were employed to study the expression of vimentin, beta-crystallin, gamma-crystallin, filensin, aquaporin 0 and the Na, K-ATPase catalytic subunit isoforms (alpha1, alpha2, alpha3) in bovine lens epithelium whole-mounts as well as lens epithelial cell cultures propagated in medium containing 10% bovine serum or in medium supplemented with bovine serum concentrations < or =4%. RESULTS: Three distinct cell types were observed in the bovine lens epithelium. The cells of the central zone were identified by a polarized distribution of two distinct Na, K-ATPase catalytic subunit isoforms, alpha1 to the apical (fiber side) and alpha3 to the basal (aqueous humor side) membranes. Lateral to the polarized central zone, was the germinative zone of cells, best characterized by perinuclear vimentin basket-like structures and the loss of polarized Na, K-ATPase catalytic subunit isoforms. Lateral to the germinative zone were the cells of the transition zone (meridinal rows) where expression of the lens specific proteins beta-crystallin, gamma-crystallin, filensin and aquaporin 0 as well as the lens fiber-, adipocyte- and brain glia-specific Na, K-ATPase catalytic subunit, alpha2 are expressed. The cultured cells propagated in medium supplemented with 10% serum bore no resemblance to any of the cells of the bovine lens epithelium whole-mounts. The cells propagated in the medium supplemented with the lower bovine serum levels resembled the differentiating fibers of the transition zone of the bovine lens epithelium whole-mounts as well as superficial cortical fibers. CONCLUSIONS: Since the low-serum lens epithelial cell cultures bear a remarkable resemblance to early differentiating fibers, they are reasonable models for the study of early fiber differentiation or prevention of differentiation. The culture conditions employed do not yield the polarized cells of the central zone. Nor has the function of these polarized cells in lens fluid, nutrient and ion homeostasis been determined.     

Identifying the role of specific motifs in the lens fiber cell specific intermediate filament phakosin

PURPOSE: Phakosin and filensin are lens fiber cell-specific intermediate filament (IF) proteins. Unlike every other cytoplasmic IF protein, they assemble into a beaded filament (BF) rather than an IF. Why the lens fiber cell requires two unique IF proteins and why and how they assemble into a structure other than an IF are unknown. In this report we test specific motifs/domains in phakosin to identify changes that that have adapted phakosin to lens-specific structure and function. METHODS: Phakosin shows the highest level of sequence identity to K18, whose natural assembly partner is K8. We therefore exchanged conserved keratin motifs between phakosin and K18 to determine whether phakosin's divergent motifs could redirect the assembly of chimeric K18 and K8. Modified proteins were bacterially expressed and purified. Assembly competence was assessed by electron microscopy. RESULTS: Substitution of the phakosin helix initiation motif (HIM) into K18 does not alter assembly with K8, establishing that the radical divergence in phakosin HIM is not by itself the mechanism by which IF assembly is redirected to BF assembly. Unexpectedly, K18 bearing phakosin HIM resulted in normal IF assembly, despite the presence of an otherwise disease-causing R-C substitution, and two helix-disrupting glycines. This disproves the widely held belief that mutation of the R is catastrophic to IF assembly. Additional data are presented that suggest normal IF assembly is dependent on sequence-specific interactions between the IF head domain and the HIM. CONCLUSIONS: In the lens fiber cell, two members of the IF family have evolved to produce BFs instead of IFs, a change that presumably adapts the IF to a fiber cell-specific function. The authors establish here that the most striking divergence seen in phakosin is not, as hypothesized, the cause of this altered assembly outcome. The authors further establish that the HIM of IFs is far more tolerant of mutations, such as those that cause some corneal dystrophies and Alexander disease, than previously hypothesized and that normal assembly involves sequence-specific interactions between the head domain and the HIM.