The inductive capacity of proteins secreted by cells of corneal epithelium

Two classes of proteins play a leading role in the mechanisms of differentiation. The first class presents structural proteins that are fundamental for the structure and function of organs. Proteins of the second class are less understood; they exist in minor quantities and realize their action only in determining the accomplishment by structural proteins of their terminal functional state. Here we try to clarify the role of peptides synthesized by the corneal epithelium in determining the fate of differentiating cells. The acting protein fractions were obtained from isolated corneas of adult pigs, cows and carps. Their inducing activities were tested by a standard method, i. e. by checking their action on the early gastrula ectoderm of Xenopus laevis. To study a possibility of cornea conservation, we used preferentially lyophilizing drying of the obtained substances. With some differences in frequency, the protein mixtures obtained from all corneas induced the appearance of neural tissue (brain), but in the case of lyophilized cow corneas lenses, ear vesicles and somites also appeared. The results of this work clearly show the absence of homology between the sources of inducing factors and the specificity of their action. The cornea is an ectodermal derivative, but its products induce neural derivatives and, moreover, after lyophilization they change their induction specificity and induce also mesodermal cell types due, presumably, to changes in the tertiary structure of protein molecules after lyophilization.     

Requirement of PDZ-containing proteins for cell cycle regulation and differentiation in the mouse lens epithelium

The roles of PDZ domain-containing proteins such as Dlg and Scrib have been well described for Drosophila; however, their requirement for mammalian development is poorly understood. Here we show that Dlg, Scrib, MAGI1, MAGI3, and MPDZ are expressed in the mouse ocular lens. We demonstrate that the increase in proliferation and defects in cellular adhesion and differentiation observed in epithelia of lenses that express E6, a viral oncoprotein that can bind to several PDZ proteins, including the human homologs of Dlg and Scrib, is dependent on E6's ability to bind these proteins via their PDZ domains. Analyses of lenses from mice carrying an insertional mutation in Dlg (dlg(gt)) show increased proliferation and proliferation in spatially inappropriate regions of the lens, a phenotype similar to that of lenses expressing E6. The results from this study indicate that multiple PDZ domain-containing proteins, including Dlg and Scrib, may be required for maintaining the normal pattern of growth and differentiation in the lens. Furthermore, the phenotypic similarities among the Drosophila dlg mutant, the lenses of dlg(gt) mice, and the lenses of E6 transgenic mice suggest that Dlg may have a conserved function in regulating epithelial cell growth and differentiation across species.     

Macrophage invasion and phagocytic activity during lens regeneration from the iris epithelium in newts

Following removal of the lens through the cornea, early stages of lens regeneration from the dorsal iris of the adult newt, Notophthalmus viridescens, were studied using light and electron microscopic observations on sectioned, plastic-embedded irises. Specimens were fixed in Karnovsky's fixative every 2 days from 0 to 12 and 15 days after lentectomy. Infiltration of the iris epithelium by macrophages and their phagocytosis of melanosomes and small fragments of iris epithelial cells were observed. These macrophages were characterized by coarse nuclear chromatin, numerous mitochondria, free ribosomes, granular endoplasmic reticulum, Golgi complexes, vesicles, lysosomes, and phagosomes containing ingested melanosomes. Lamellipodia of varying length projected from their surface. Most of the cells lying on or close to the posterior surface of the iris could be identified as macrophages by these criteria. During this period, there was enlargement of the intercellular spaces within the iris epithelium. The iris epithelial cells near the margin of the pupil elongated, lost their melanin pigment and some associated cytoplasm, and acquired abundant free polyribosomes to form a lens vesicle of depigmented cells.     

TRPV4 in porcine lens epithelium regulates hemichannel-mediated ATP release and Na-K-ATPase activity

In several tissues, transient receptor potential vanilloid 4 (TRPV4) channels are involved in the response to hyposmotic challenge. Here we report TRPV4 protein in porcine lens epithelium and show that TRPV4 activation is an important step in the response of the lens to hyposmotic stress. Hyposmotic solution (200 mosM) elicited ATP release from intact lenses and TRPV4 antagonists HC 067047 and RN 1734 prevented the release. In isosmotic solution, the TRPV4 agonist GSK1016790A (GSK) elicited ATP release. When propidium iodide (PI) (MW 668) was present in the bathing medium, GSK and hyposmotic solution both increased PI entry into the epithelium of intact lenses. Increased PI uptake and ATP release in response to GSK and hyposmotic solution were abolished by a mixture of agents that block connexin and pannexin hemichannels, 18α-glycyrrhetinic acid and probenecid. Increased Na-K-ATPase activity occurred in the epithelium of lenses exposed to GSK and 18α-glycyrrhetinic acid + probenecid prevented the response. Hyposmotic solution caused activation of Src family kinase and increased Na-K-ATPase activity in the lens epithelium and TRPV4 antagonists prevented the response. Ionomycin, which is known to increase cytoplasmic calcium, elicited ATP release, the magnitude of which was no greater when lenses were exposed simultaneously to ionomycin and hyposmotic solution. Ionomycin-induced ATP release was significantly reduced in calcium-free medium. TRPV4-mediated calcium entry was examined in Fura-2-loaded cultured lens epithelium. Hyposmotic solution and GSK both increased cytoplasmic calcium that was prevented by TRPV4 antagonists. The cytoplasmic calcium rise in response to hyposmotic solution or GSK was abolished when calcium was removed from the bathing solution. The findings are consistent with hyposmotic shock-induced TRPV4 channel activation which triggers hemichannel-mediated ATP release. The results point to TRPV4-mediated calcium entry that causes a cytoplasmic calcium increase which is an essential early step in the mechanism used by the lens to sense and respond to hyposmotic stress.     

ERM proteins of the lens

Ezrin and radixin and protein 4.1 were detected in the lens of the eye. These proteins were mainly present in the young elongating cortical fiber cells and localized to the plasma membranes. Moesin was not detected. Ezrin, radixin, and protein 4.1 provide another means whereby actin is linked to the plasma membrane in addition to the known adherens junctions in the lens.     

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.     

Transport of fluid by lens epithelium

We report for the first time that cultured lens epithelial celllayers and rabbit lenses in vitro transport fluid. Layers of the TN4mouse cell line and bovine cell cultures were grown to confluence onpermeable membrane inserts. Fluid movement across cultured layers andexcised rabbit lenses was determined by volume clamp (37°C).Cultured layers transported fluid from their basal to their apicalsides against a pressure head of 3 cmH₂O. Rates were (inµl · h¹ · cm²)3.3 ± 0.3 for TN4 cells (n = 27) and 4.7 ± 1.0 for bovine layers (n = 6). Quinidine, a blocker ofK⁺ channels, andp-chloromercuribenzenesulfonate andHgCl₂, inhibitors of aquaporins,inhibited fluid transport. Rabbit lenses transported fluid from theiranterior to their posterior sides against a2.5-cmH₂O pressure head at 10.3 ± 0.62 µl · h¹ · lens¹(n = 5) and along the same pressurehead at 12.5 ± 1.1 µl · h¹ · lens¹(n = 6). We calculate that this flowcould wash the lens extracellular space by convection about once every2 h and therefore might contribute to lens homeostasis and transparency.     

Intraspecific variation in the lens proteins

A review of the literature indicates that intraspecific variation among the lens proteins (crystallins) is almost invariably quantitative rather than qualitative. Lens extracts were examined from inbred strains of the laboratory mouse, rat, and guinea pig and from domestic breeds of sheep. Differences in the mobilities of protein bands after electrophoresis in polyacrylamide gels were never found to be greater than the variation observed when a sample was repeatedly subjected to electrophoresis. Differences, however, were observed between widely separated populations of the bank vole (Clethrionomys glareolus). In bank voles and mice, there were variations in the intensities of bands. Electrophoresis of extracts in the presence of 6 m urea indicated that there were no major differences between six mouse strains in the subunits constituting their - and -crystallins. More detailed examination of -crystallins from two mouse strains by isoelectric focusing and amino acid analysis supported this conclusion.This work was carried out while one of the authors (T.H.D.) was supported by a Medical Research Council Research Studentship and a European Molecular Biology Organisation Fellowship. A grant from the Edinburgh University Weir Memorial Fund allowed the collection of some of the Yugoslavian bank voles.     

Concentration dependence of proteoglycan diffusion

The mutual diffusion coefficient of the bovine nasal cartilage proteoglycan subunit is found to increase rapidly with increasing concentration and decreasing ionic strength. These results have been obtained by analysis of the boundary relaxation of concentration gradients in the analytical ultracentrifuge by schlieren optics. The diffusion behavior can be understood in terms of the nonideality of the proteoglycan. The magnitude of the nonideality is dominated by charge interactions, whereas the influence of molecular size and associated excluded-volume interactions is small. The concentration dependence of the apparent diffusion coefficient of the proteoglycan subunit from dynamic light scattering was found, in contrast, to decrease with increasing concentration. Computer simulation of the dynamic light scattering suggests that the presence of a small population of aggregates may account for the difference in the two types of diffusion measurement due to their marked influence on the scattering.     

Cell cycle synchrony in the developing chicken lens epithelium.

Synchronous oscillations of DNA synthesis and histone 2B mRNA expression occur during normal development of 13- to 16-day-old embryonic chicken lens epithelium. At least four cycles were observed with peak values of DNA synthesis and histone 2B mRNA 5 to 10 times greater than baseline values. Fourier analysis of DNA synthesis identified a statistically significant oscillatory period of 18 hr, the approximate length of the cell cycle at this age. Minor components of 7-9 and 12 hr were also identified in the data sets. Lenses labeled with 3H-thymidine and analyzed by autoradiography at 13.8 days of embryogenesis revealed more than twice the number of labeled nuclei at this time than in lenses labeled 9 hr later; histone 2B mRNA followed this same pattern. These findings demonstrate that a significant population of cells is synchronized with respect to the cell cycle in the developing lens epithelium in ovo. The temporal pattern of mitosis may be the basis of the fiber cell architecture and consequent lens transparency.     

Glial fibrillary acidic protein is localized in the lens epithelium

The epithelium of the mouse lens stains intensely with antisera to glial fibrillary acidic protein (GFAP). A protein co-migrating with GFAP and immunoreactive with antisera to GFAP can be demonstrated in lens epithelium protein extracts by immunoblots. GFAP has previously been considered unique to cells of neural origin, but this study demonstrates that ectodermally derived cells express GFAP or a highly similar protein.     

The lens epithelium in ocular health and disease

The lens arises from invagination of head ectoderm during embryonic development and in the adult has a relatively simple structure, comprising just two cell types (epithelial and fibre cells). Its isolation from nerves and blood vessels in the adult make it a tractable model to investigate mechanisms that regulate epithelial cells. A major focus in lens research in the past 50 years has been on the differentiation of fibre cells from epithelial cells. Hence, there has been much interest in the role of signalling systems regulating fibre cell differentiation during development. In contrast, the signalling systems that control the formation and maintenance of the lens epithelium have, until recently, been largely ignored or incidental to studies on differentiation or cataract. One notable example has been the identification of signals that underlie epithelial-mesenchymal transition (EMT) that characterizes anterior subcapsular cataract (ASC) and posterior capsule opacification (PCO). Recent data indicate that normal epithelial phenotype is regulated by several key signalling systems, including receptor tyrosine kinase receptors acting via the MAPK and Akt pathways, Wnt, Notch as well as extracellular matrix cues and possibly the Sal-Warts-Hippo pathway. Here we have shifted emphasis onto molecular mechanisms that regulate the establishment, maintenance and function of the lens epithelium.     

Characterization of abnormal proteins in the soluble lens proteins of CatFraser mice

The murine mutation CatFraser causes a cataract in both the mutant heterozygote (C/+) and mutant homozygote (C/C). Our previous electrophoretic studies detected, in the lenses of both mutant genotypes, several proteins which did not appear to be present in normal lenses. Here we show, using more sensitive methods, that traces of these proteins previously characterized as abnormal are in fact present in normal lenses. Furthermore, these proteins have a primary structure very similar to that of the alpha-crystallins. We conclude that the mutation accelerates the degradation of alpha-crystallin, which in the normal lens proceeds at a very slow rate.     

Concentration dependence of protein diffusion.

The concentration dependence of protein self-diffusion constants is described by a free volume diffusion theory which accounts for the effects of local protein concentration fluctuations.