The effect of fibre cell remodelling on the power and optical quality of the lens.

Vertebrate eye lenses are uniquely adapted to form a refractive index gradient (GRIN) for improved acuity, and to grow slowly in size despite constant cell proliferation. The mechanisms behind these adaptations remain poorly understood. We hypothesize that cell compaction contributes to both. To test this notion, we examined the relationship between lens size and shape, refractive characteristics and the cross-sectional areas of constituent fibre cells in mice of different ages. We developed a block-face imaging method to visualize cellular cross sections and found that the cross-sectional areas of fibre cells rose and then decreased over time, with the most significant reduction occurring in denucleating cells in the adult lens cortex, followed by cells in the embryonic nucleus. These findings help reconcile differences between the predictions of lens growth models and empirical data. Biomechanical simulations suggested that compressive forces generated from continuous deposition of fibre cells could contribute to cellular compaction. However, optical measurements revealed that the GRIN did not mirror the pattern of cellular compaction, implying that compaction alone cannot account for GRIN formation and that additional mechanisms are likely to be involved.

Single-cell RNA-sequencing analysis of the ciliary epithelium and contiguous tissues in the mouse eye.

The ciliary epithelium plays a central role in ocular homeostasis but cells of the pigmented and non-pigmented layers are difficult to isolate physically and study. Here we used single-cell RNA-sequencing (scRNA-seq) to analyze the transcriptional signatures of cells harvested from the ciliary body and contiguous tissues. Microdissected tissue was dissociated by collagenase digestion and the transcriptomes of individual cells were obtained using a droplet-based scRNA-seq approach. In situ hybridization was used to verify the expression patterns of selected differentially-expressed genes. High quality transcriptomes were obtained from 10,024 cells and unsupervised clustering distinguished 22 cell types. Although efforts were made to specifically isolate the ciliary body, approximately half of the sequenced cells were derived from the adjacent retina. Cluster identities were assigned using expression of canonical markers or cluster-specific genes. The transcriptional signature of cells in the PCE and NPCE were distinct from each other and from cells in contiguous tissues. PCE cell transcriptomes were characterized by genes involved in melanin synthesis and transport proteins such as Slc4a4. Among the most differentially expressed genes in NPCE cells were those encoding members of the Zic family of transcription factors (Zic1, 2, 4), collagen XVIII (Col18a1), and corticotrophin-releasing hormone-binding protein (Crhbp). The ocular melanocyte population was distinguished by expression of the gap junction genes Gjb2 and Gjb6. Two fibroblast signatures were detected in the ciliary body preparation and shown by in situ hybridization to correspond to uveal and scleral populations. This cell atlas for the ciliary body and contiguous layers represents a useful resource that may facilitate studies into the development of the ciliary epithelium, the production of the aqueous and vitreous humors, and the synthesis of the ciliary zonule.

Latent-transforming growth factor beta-binding protein-2 (LTBP-2) is required for longevity but not for development of zonular fibers.

Latent-transforming growth factor beta-binding protein 2 (LTBP-2) is a major component of arterial and lung tissue and of the ciliary zonule, the system of extracellular fibers that centers and suspends the lens in the eye. LTBP-2 has been implicated previously in the development of extracellular microfibrils, although its exact role remains unclear. Here, we analyzed the three-dimensional structure of the ciliary zonule in wild type mice and used a knockout model to test the contribution of LTBP-2 to zonule structure and mechanical properties. In wild types, zonular fibers had diameters of 0.5-1.0 micrometers, with an outer layer of fibrillin-1-rich microfibrils and a core of fibrillin-2-rich microfibrils. LTBP-2 was present in both layers. The absence of LTBP-2 did not affect the number of fibers, their diameters, nor their coaxial organization. However, by two months of age, LTBP-2-depleted fibers began to rupture, and by six months, a fully penetrant ectopia lentis phenotype was present, as confirmed by in vivo imaging. To determine whether the seemingly normal fibers of young mice were compromised mechanically, we compared zonule stress/strain relationships of wild type and LTBP-2-deficient mice and developed a quasi-linear viscoelastic engineering model to analyze the resulting data. In the absence of LTBP-2, the ultimate tensile strength of the zonule was reduced by about 50%, and the viscoelastic behavior of the fibers was altered significantly. We developed a harmonic oscillator model to calculate the forces generated during saccadic eye movement. Model simulations suggested that mutant fibers are prone to failure during rapid rotation of the eyeball. Together, these data indicate that LTBP-2 is necessary for the strength and longevity of zonular fibers, but not necessarily for their formation.

Changes in adhesion complexes define stages in the differentiation of lens fiber cells.

PURPOSE: During their differentiation, lens fiber cells elongate, detach from the lens capsule, associate at the sutures, and degrade all cytoplasmic membrane-bound organelles. Changes in the expression or organization of cell adhesion and cytoskeleton-associated proteins were correlated with these events during fiber cell differentiation in chicken embryos. METHODS: Fixed or living lenses were sliced with a tissue slicer, permeabilized or extracted with detergents, stained with antibodies or fluorescent-labeled phalloidin, and viewed with a confocal microscope. The distribution of N-cadherin in elongating and mature fiber cells was determined by Western blot analysis. Reverse transcription-polymerase chain reaction (RT-PCR) was used to determine the distribution of vinculin and paxillin transcripts. RESULTS: Staining for N-cadherin and band 4.1 protein decreased soon after fiber cells detached from the capsule. Detergent extraction of lens sections and Western blots of dissected lens regions showed that much of this decrease in staining was due to epitope masking. Vinculin immunoreactivity was barely detectable on the lateral membranes of elongating fiber cells but increased markedly once these cells reached their maximum length and formed the sutures. Staining for paxillin was also low in elongating fiber cells but increased late in fiber cell differentiation, just before the cells destroyed their membrane-bound organelles. Spectrin and ankyrin immunoreactivity did not change when fiber cells reached the sutures. Staining for F-actin increased transiently in cells that had just reached the sutures. Messenger RNAs for vinculin and paxillin were more abundant in maturing than in elongating fiber cells. CONCLUSIONS: The adhesion complexes of lens fiber cells change in organization and composition soon after these cells finish elongating and detach from the capsule. Increased staining for vinculin and paxillin defines distinct stages of fiber cell differentiation that are intermediate between the completion of cell elongation and the time when lens fiber cells degrade their membrane-bound organelles. Remodeling adhesion complexes during fiber cell maturation may assure the stability of fiber-fiber associations, once these cells are no longer transcriptionally active.

Lens epithelial cells derived from alphaB-crystallin knockout mice demonstrate hyperproliferation and genomic instability.

alphaB-crystallin is a member of the small heat shock protein family and can act as a molecular chaperone preventing the in vitro aggregation of other proteins denatured by heat or other stress conditions. Expression of alphaB-crystallin increases in cells exposed to stress and enhanced in tumors of neuroectodermal origin and in many neurodegenerative diseases. In the present study, we examined the properties of lens epithelial cells derived from mice in which the alphaB-crystallin gene had been knocked out. Primary rodent cells immortalize spontaneously in tissue culture with a frequency of 10(-5) to 10(-6). Primary lens epithelial cells derived from alphaB-crystallin-/- mice produced hyperproliferative clones at a frequency of 7.6 x 10(-2), four orders of magnitude greater than predicted by spontaneous immortalization (1). Hyperproliferative alphaB-crystallin-/- cells were shown to be truly immortal since they have been passaged for more than 100 population doublings without any diminution in growth potential. In striking contrast to the wild-type cells, which were diploid, the alphaB-crystallin-/- cultures had a high proportion of tetraploid and higher ploidy cells, indicating that the loss of alphaB-crystallin is associated with an increase in genomic instability. Further evidence of genomic instability of alphaB-crystallin-/- cells was observed when primary cultures were infected with Ad12-SV40 hybrid virus. In striking contrast to wild-type cells, alphaB-crystallin-/- cells expressing SV40 T antigen exhibited a widespread cytocidal response 2 to 3 days after attaining confluence, indicating that SV40 T antigen enhanced the intrinsic genomic instability of alphaB-crystallin-/- lens epithelial cells. These observations suggest that the widely distributed molecular chaperone alphaB-crystallin may play an important nuclear role in maintaining genomic integrity.

Optical dysfunction of the crystalline lens in aquaporin-0-deficient mice.

Aquaporin-0 (AQP0), a water transport channel protein, is the major intrinsic protein (MIP) of lens fiber cell plasma membranes. Mice deficient in the gene for AQP0 (Aqp0, Mip) were generated from a library of gene trap embryo stem cells. Sequence analysis showed that the gene trap vector had inserted into the first exon of Aqp0, causing a null mutation as verified by RNA blotting and immunochemistry. At 3 wk of age (postnatal day 21), lenses from null mice (Aqp0(-/-)) contained polymorphic opacities, whereas lenses from heterozygous mice (Aqp0(+/-)) were transparent and did not develop frank opacities until approximately 24 wk of age. Osmotic water permeability values for Aqp0(+/-) and Aqp0(-/-) lenses were reduced to approximately 46% and approximately 20% of wild-type values, respectively, and the focusing power of Aqp0(+/-) lenses was significantly lower than that of wild type. These findings show that heterozygous loss of AQP0 is sufficient to trigger cataractogenesis in mice and suggest that this MIP is required for optimal focusing of the crystalline lens.

Disruption of lens fiber cell architecture in mice expressing a chimeric AQP0-LTR protein.

Aquaporin-0 (AQP0) is the major intrinsic protein of lens fiber cells and the founder member of the water channel gene family. Here we show that disruption of the AQP0 gene by an early transposon (ETn) element results in expression of a chimeric protein, comprised of approximately 75% AQP0 and approximately 25% ETn long terminal repeat (LTR) sequence, in the cataract Fraser (CatFr) mouse lens. Immunoblot analysis showed that mutant AQP0-LTR was similar in mass to wild-type AQP0. However, immunofluorescence microscopy revealed that AQP0-LTR was localized to intracellular membranes rather than to plasma membranes of lens fiber cells. Heterozygous CatFr lenses were similar in size to wild-type but displayed abnormal regions of translucence and light scattering. Scanning electron microscopy further revealed that mature fiber cells within the core of the heterozygous CatFr lens failed to stratify into uniform, concentric growth shells, suggesting that the AQP0 water channel facilitates the development of the unique cellular architecture of the crystalline lens.

Differential protective activity of alpha A- and alphaB-crystallin in lens epithelial cells.

alphaA- and alphaB-crystallins are molecular chaperones expressed at low levels in lens epithelial cells, and their expression increases dramatically during differentiation to lens fibers. However, the functions of alphaA- and alphaB-crystallins in lens epithelial cells have not been studied in detail. In this study, the relative ability of alphaA- and alphaB-crystallin, in protecting lens epithelial cells from apoptotic cell death was determined. The introduction of alphaA-crystallin in the transformed human lens epithelial (HLE) B-3 lens epithelial cell line (which expresses low endogenous levels of alphaB-crystallin) led to a nearly complete protection of cell death induced by staurosporine, Fas monoclonal antibody, or the cytokine tumor necrosis factor alpha. To further study the relative protective activities of alphaA- and alphaB-crystallins, we created a cell line derived from alphaA-/-alphaB-/- double knockout mouse lens epithelia by infecting primary cells with Ad12-SV40 hybrid virus. The transformed cell line alphaAalphaBKO1 derived from alphaA/alphaB double knockout cells was transfected with alphaA- or alphaB-crystallin cDNA contained in pCIneo mammalian expression vector. Cells expressing different amounts of either alphaA-crystallin or alphaB-crystallin were isolated. The ability of alphaA- or alphaB-crystallin to confer protection from apoptotic cell death was determined by annexin labeling and flow cytometry of staurosporine- or UVA- treated cells. The results indicate that the anti-apoptotic activity of alphaA-crystallin was two to three-fold higher than that of alphaB-crystallin. Our work suggests that comparing the in vitro annexin labeling of lens epithelial cells is an effective way to measure the protective activity of alphaA- and alphaB-crystallin. Since the expression of alphaA-crystallin is largely restricted to the lens, its greater protective effect against apoptosis suggests that it may play a significant role in protecting lens epithelial cells from stress.

Expression of autofluorescent proteins reveals a novel protein permeable pathway between cells in the lens core.

The lens of the eye is composed of concentric layers of tightly packed fiber cells. The oldest fibers, those in the lens core, lose their nuclei and other organelles during terminal differentiation. This is thought to ensure the clarity of the lens. The anucleated core fibers are sustained by gap junction-mediated communication with metabolically active cells near the lens surface. In this study, we expressed autofluorescent proteins and microinjected fluorescent markers to probe cell-to-cell communication in different regions of the developing lens. Our data indicate that a novel cell-cell diffusion pathway becomes patent in the lens core during development. This pathway is remarkable in that it is permeable to proteins and other large molecules and is thus distinct from gap junctions. Diffusion of large molecules probably occurs through regions of membrane fusion observed between neighboring cells in the lens core. Further direct evidence for a continuous plasma membrane system was provided by the observation that exogenous membrane proteins expressed in one core fiber cell were able to diffuse laterally into the membranes of adjacent fibers. Thus, the lens core appears to represent a true syncytium within which both membrane proteins and cytoplasmic proteins freely diffuse. Significantly, the outermost edge of the core syncytium encompasses a shell of nucleated, transcriptionally-competent, fiber cells. This arrangement could facilitate the delivery of newly synthesized protein components to the aged and metabolically quiescent cells in the center of the lens.

Three-dimensional organization of primary lens fiber cells.

PURPOSE: To visualize the three-dimensional organization of primary lens fiber cells. METHODS: The gene for Green Fluorescent Protein (GFP) was introduced into the lens vesicle using two different vector systems: a replication deficient adenovirus or an expression plasmid. Injected embryos were allowed to develop for several days and then were examined by confocal microscopy. RESULTS: Injection of either vector resulted in GFP expression in primary fiber cells. GFP-expressing cells were heterogeneous in shape and length. Some regions of the fibers were varicose, with diameters >10 microm; regions between the varicosities were often extremely thin, with diameters of <2 microm. No differences in the morphologies of GFP-expressing cells were noted between adenovirus and plasmid-injected lenses, suggesting that the irregular, undulating, appearance of the primary fibers was not the result of viral infection. Three-dimensional reconstruction of primary fiber cells revealed that, by E6, the posterior tips of the fibers had detached from the lens capsule. The anterior fiber tips remained in contact with the overlying epithelium for 1 to 2 additional days, demonstrating that the formation of the anterior and posterior sutures was asynchronous. CONCLUSIONS: The three-dimensional cellular organization of GFP-expressing cells is consistent with previous analyses of fiber cell morphology in the embryonic nucleus of adult human and bovine lenses. The present data confirm that the disorganized appearance of primary fiber cells observed in adult lenses is largely a reflection of developmental processes rather than a consequence of aging.

Stimulation of quiescent corneal endothelial cells by direct delivery of the SV40 large T-antigen protein.

PURPOSE: To determine whether the delivery of the SV40 large T-antigen is a feasible method for transiently inducing proliferation of corneal endothelial cells. METHODS: Liposome-mediated delivery of proteins into bovine corneal endothelial cells (BCEC) was utilized in this study. Initially, beta-galactosidase was used as a marker protein for cell delivery and cells were assayed colorimetrically for beta-galactosidase activity. Subsequently, SV40 large T-antigen protein was introduced into BCEC and positive cells were identified by immunohistochemistry 24 hours after liposome-protein treatment. Quiescent BCECs were double-labeled using BrdU as a measure of de novo DNA synthesis and the SV40 large T-antigen was detected by standard immunohistochemical methods. RESULTS: Beta-galactosidase or SV40 large T antigen were introduced into BCECs using liposome transfer methods. The transfer efficiency of beta-galactosidase was > 30% of the cells. SV40 large T antigen was successfully introduced and was localized to the nuclei of BCECs. The treatment of quiescent BCECs with large T antigen caused an increase in BrdU incorporation. Co-labeling confirmed that only cells containing SV40 large T antigen were positive for de novo DNA synthesis. CONCLUSIONS: This study demonstrates that proteins can be inserted directly into corneal endothelial cells. In the case of the SV40 large T-antigen, the protein localized to the nucleus and maintained its bioactivity by inducing DNA synthesis. This finding suggests that liposome-mediated delivery of transforming proteins could be a method to transiently induce corneal endothelial cell proliferation.

The role of MIP in lens fiber cell membrane transport.

MIP has been hypothesized to be a gap junction protein, a membrane ion channel, a membrane water channel and a facilitator of glycerol transport and metabolism. These possible roles have been indirectly suggested by the localization of MIP in lens gap junctional plaques and the properties of MIP when reconstituted into artificial membranes or exogenously expressed in oocytes. We have examined lens fiber cells to see if these functions are present and whether they are affected by a mutation of MIP found in CatFr mouse lens. Of these five hypothesized functions, only one, the role of water channel, appears to be true of fiber cells in situ. Based on the rate of volume change of vesicles placed in a hypertonic solution, fiber cell membrane lipids have a low water permeability (pH2O) on the order of 1 micron/sec whereas normal fiber cell membrane pH2O was 17 micron/sec frog, 32 micron/sec rabbit and 43 micron/sec mouse. CatFr mouse lens fiber cell pH2O was reduced by 13 micron/sec for heterozygous and 30 micron/sec for homozygous mutants when compared to wild type. Lastly, when expressed in oocytes, the pH2O conferred by MIP is not sensitive to Hg2+ whereas that of CHIP28 (AQP1) is blocked by Hg2+. The fiber cell membrane pH2O was also not sensitive to Hg2+ whereas lens epithelial cell pH2O (136 micron/sec in rabbit) was blocked by Hg2+. With regard to the other hypothesized roles, fiber cell membrane or lipid vesicles had a glycerol permeability on the order of 1 nm/sec, an order of magnitude less than that conferred by MIP when expressed in oocytes. Impedance studies were employed to determine gap junctional coupling and fiber cell membrane conductance in wild-type and heterozygous CatFr mouse lenses. There was no detectable difference in either coupling or conductance between the wild-type and the mutant lenses.

Exogenous gene expression and protein targeting in lens fiber cells.

PURPOSE: To test the ability of lens fiber cells at various stages of differentiation to transcribe and translate microinjected DNA templates. METHODS: Expression plasmids encoding green fluorescent protein (GFP) or a GFP-tagged membrane protein (human CD46) were microinjected into organ-cultured embryonic chicken lenses. Protein expression was visualized by confocal microscopy. RESULTS: GFP expression was detected within 12 hours of microinjection, evenly distributed throughout the cytoplasm of the injected cell. All nucleated fiber cells were competent to express GFP, whereas the anucleated central fiber cells were not. When GFP was fused to the C-terminal of CD46, the fusion protein was synthesized intact and properly inserted in the fiber cell plasma membrane. In contrast, N-terminal fusions were cleaved during synthesis, resulting in retention of the GFP tag in the endoplasmic reticulum. CONCLUSIONS: Microinjection of expression plasmids is an effective technique for introducing exogenous genes into individual fiber cells. With this approach, the results show that fiber cells are transcriptionally and translationally competent until the time of organelle loss, and that fiber cells deep within the lens are capable of synthesizing new plasma membrane proteins. The techniques described here should have broad application in studies of fiber cell differentiation and provide a useful complement to conventional transgenic approaches.

Molecular architecture of the lens fiber cell basal membrane complex.

Lens fiber cells are transparent, highly elongated, epithelial cells. Because of their unusual length these cells represent a novel model system to investigate aspects of epithelial cell polarity. In this study, we examined the fiber cell basal membrane complex (BMC). The BMC anchors fiber cells to the lens capsule and facilitates their migration across the capsule. Confocal microscopy revealed that bundled actin filaments converge beneath the center of each BMC and insert into the lateral membrane at points enriched in N-cadherin. Two other contractile proteins, caldesmon and myosin, were enriched in the BMC, co-localizing with f-actin bundles. The actin/N-cadherin complex formed a hexagonal lattice, cradling the posterior face of the lens. Removal of the capsule caused the tips of the fiber cells to break off, remaining attached to the stripped capsule. This provided a method for assaying cell adhesion and purifying BMC components. Fiber cell adhesion required Mg2+ and/or Ca2+ and was disrupted by incubation with beta1 integrin antibody. BMC proteins were compared with samples from the neighboring lateral membrane. Although some components were common to both samples, others were unique to the BMC. Furthermore, some lateral membrane proteins, most notably lens major intrinsic protein (MIP), were excluded from the BMC. Western blotting of BMC preparations identified several structural proteins originally found in focal adhesions and two kinases, FAK and MLCK, previously undescribed in the lens. These data suggest that the BMC constitutes a distinct membrane domain in the lens. The structural organization of the BMC suggests a role in shaping the posterior lens face and hence the refractive properties of the eye.

Cultured chicken embryo lens cells resemble differentiating fiber cells in vivo and contain two kinetic pools of connexin56.

The lens is an avascular organ in which gap junctions play a pivotal role for cell physiology and transparency. Here we evaluate a lens culture system as a model for studies of lens gap junction dynamics. In culture, chicken embryo lens cells initially form a monolayer of epithelial cells. Subsequently, the epithelial cells differentiate into lentoids, birefringent multicellular structures composed of fiber-like cells. We examined the cultures for the expression of cellular markers and lens fiber specific proteins using immunofluorescence and immunoblot analysis. We also determined the half-life of connexin56 (Cx56), a fiber-specific gap junction protein. All lens cells in culture expressed actin, endoplasmic reticulum proteins and N-cadherin. Only lentoid cells expressed the lens fiber connexins, Cx45.6 and Cx56. Cx56 localized at appositional membranes and did not co-localize with endoplasmic reticulum proteins or N-cadherin. Two pools of Cx56 were detected in these cultures, one with a half-life of a few hours and the other with a half-life of days. The two pools contained phosphorylated forms of Cx56 of different apparent molecular weights. These results suggest that lens cells in culture can be used as a model for the study of lens biology. They also suggest that phosphorylation of Cx56 might be regulating the stability of the protein.

The molecular chaperone alphaA-crystallin enhances lens epithelial cell growth and resistance to UVA stress.

alphaA-Crystallin (alphaA) is a member of the small heat shock protein (sHSP) family and has the ability to prevent denatured proteins from aggregating in vitro. Lens epithelial cells express relatively low levels of alphaA, but in differentiated fiber cells, alphaA is the most abundant soluble protein. The lenses of alphaA-knock-out mice develop opacities at an early age, implying a critical role for alphaA in the maintenance of fiber cell transparency. However, the function of alpha-crystallin in the lens epithelium is unknown. To investigate the physiological function of alphaA in lens epithelial cells, we used the following two systems: alphaA knock-out (alphaA(-/-)) mouse lens epithelial cells and human lens epithelial cells that overexpress alphaA. The growth rate of alphaA(-/-) mouse lens epithelial cells was reduced by 50% compared with wild type cells. Cell cycle kinetics, measured by fluorescence-activated cell sorter analysis of propidium iodide-stained cells, indicated a relative deficiency of alphaA(-/-) cells in the G2/M phases. Exposure of mouse lens epithelial cells to physiological levels of UVA resulted in an increase in the number of apoptotic cells in the cultures. Four hours after irradiation the fraction of apoptotic cells in the alphaA(-/-) cultures was increased 40-fold over wild type. In cells lacking alphaA, UVA exposure modified F-actin, but actin was protected in cells expressing alphaA. Stably transfected cell lines overexpressing human alphaA were generated by transfecting extended life span human lens epithelial cells with the mammalian expression vector construct pCI-neoalphaA. Cells overexpressing alphaA were resistant to UVA stress, as determined by clonogenic survival. alphaA remained cytoplasmic after exposure to either UVA or thermal stress indicating that, unlike other sHSPs, the protective effect of alphaA was not associated with its relocalization to the nucleus. These results indicate that alphaA has important cellular functions in the lens over and above its well characterized role in refraction.

Fiber cell denucleation in the primate lens.

PURPOSE: To determine the morphologic and biochemical events preceding the breakdown of fiber cell nuclei in the primate lens. METHODS: Monkey lens slices were labeled with fluorescent probes and optically sectioned using a confocal microscope. The distribution of nuclear histones was visualized by immunofluorescence. DNA and cellular membranes were imaged simultaneously by staining with SYTO 17 and 3,3'-dihexyloxacarbocyanine iodide, respectively. The condition of fiber cell DNA during differentiation was determined by an in situ DNA fragmentation assay. The assay was adapted to allow the detection of DNA fragments with 3'-OH or 3'-PO4 termini. RESULTS: Monkey lens fiber nuclei passed through distinct stages before disintegrating. In the outer cell layers, the nuclei were large, smooth, and oval-shaped with prominent nucleoli. Deeper in the lens, they had a flattened profile with whorls of membranous material and nucleic acid accumulated at one end. At this point, histone immunofluorescence was reduced and the nucleoli had a characteristic, spoked appearance. At the border of the organelle-free zone, the intracellular membranes (including the nuclear envelope) disappeared, and particulate material was released from the nuclei into the cytoplasm. This material was stained by SYTO-17 and the DNA fragmentation assay, indicating that it contained fragmented DNA with 3'-OH termini. CONCLUSIONS: The denucleation process in the primate lens differs from that described recently in the embryonic chicken lens. In particular, the extrusion of nuclear material and persistence of DNA-rich particles in the fiber cytoplasm are novel features. One similarity between the denucleation process in these species is the appearance of 3'-OH ends in the DNA after the loss of the nuclear membrane.

Chromatin degradation in differentiating fiber cells of the eye lens.

During development, the lens of the eye becomes transparent, in part because of the elimination of nuclei and other organelles from the central lens fiber cells by an apoptotic-like mechanism. Using confocal microscopy we showed that, at the border of the organelle-free zone (OFZ), fiber cell nuclei became suddenly irregular in shape, with marginalized chromatin. Subsequently, holes appeared in the nuclear envelope and underlying laminae, and the nuclei collapsed into condensed, spherical structures. Nuclear remnants, containing DNA, histones, lamin B2, and fragments of nuclear membrane, were detected deep in the OFZ. We used in situ electrophoresis to demonstrate that fragmented DNA was present only in cells bordering the OFZ. Confocal microscopy of terminal deoxynucleotidyl transferase (TdT)-labeled lens slices confirmed that DNA fragmentation was a relatively late event in fiber differentiation, occurring after the loss of the nuclear membrane. DNA fragments with 3'-OH or 3'-PO(4) ends were not observed elsewhere in the lens under normal conditions, although they could be produced by pretreatment with DNase I or micrococcal nuclease, respectively. Dual labeling with TdT and an antibody against protein disulfide isomerase, an ER-resident protein, revealed a distinct spatial and temporal gap between the disappearance of ER and nuclear membranes and the onset of DNA degradation. Thus, fiber cell chromatin disassembly differs significantly from classical apoptosis, in both the sequence of events and the time course of the process. The fact that DNA degradation occurs only after the disappearance of mitochondrial, ER, and nuclear membranes suggests that damage to intracellular membranes may be an initiating event in nuclear breakdown.

Lens-preferred activity of chicken delta 1- and delta 2-crystallin enhancers in transgenic mice and evidence for retinoic acid-responsive regulation of the delta 1-crystallin gene.

There are two tandemly linked delta-crystallin genes [5' delta 1 -delta 2 3'] in the chicken, with the delta 1-crystallin gene being expressed much more highly (50-100-fold) in the embryonic lens than the delta 2-crystallin gene. Previous transfection experiments have shown that a lens-preferred enhancer exists in the third intron of each chicken delta-crystallin gene. In the present investigation we have used transgenic mice to establish that both the chicken delta 1- and delta 2-crystallin enhancers are preferentially active in the mouse lens in combination with their homologous promoter and the chloramphenicol acetyltransferase (CAT) reporter gene. The promoter/ CAT constructs lacking the enhancers were inactive in the transgenic mice. In one case, a truncated delta 2-crystallin promoter (-308/+24) in combination with the enhancer was also active in the Purkinje cells of the cerebellum of the transgenic mice, which could prove useful in future experiments. Finally, retinoic acid receptors (RAR beta) activated the delta 1-crystallin, but not the delta 2-crystallin enhancer in teh recombinant plasmids in cotransfected embryonic chicken lens epithelial cells treated with retinoic acid. This activation did not occur when using the care enhancer (fragment B4) lacking surrounding flanking sequences (fragment B3 and B5) of the enhancer. Together these experiments show that the chicken delta-crystallin enhancers show lens-preference in transgenic mice despite the absence of delta-crystallin in this species and add retinoic acid nuclear receptors to the growing list of transcription factors (including Pax-6, Sox-2, and delta EF3) that directly or indirectly contribute to the high expression of the delta 1-crystallin gene in the lens.

Mutations in the founder of the MIP gene family underlie cataract development in the mouse.

The major intrinsic protein (MIP) of the vertebrate eye lens is the first identified member of a sequence-related family of cell-membrane proteins that appears to have evolved by gene duplication. Several members of the MIP family transport water (aquaporins), glycerol and other small molecules in microbial, plant and animal cells. Mutations in two aquaporin homologues of MIP underlie an autosomal recessive form of nephrogenic diabetes insipidus and absence of the Colton blood group antigens in humans, whereas, mutation of a third MIP-like gene underlies 'big brain' development in Drosophila. Here we show that distinct mutations in the murine Mip gene underlie one form of autosomal dominant cataract in the mouse. The cataract Fraser mutation is a transposon-induced splicing error that substitutes a long terminal repeat sequence for the carboxy-terminus of MIP. The lens opacity mutation is an amino-acid substitution that inhibits targeting of MIP to the cell-membrane. These allelic cataract mutations provide the first direct evidence that MIP plays a crucial role in the development of a transparent eye lens.