Microtubules: a major cytoskeletal component of the human lens

Genome-wide DNA methylation profiles may reveal new possible epigenetic pathogenesis of sporadic congenital cataract

Aim: To investigate the possible epigenetic pathogenesis of sporadic congenital cataract. Materials & methods: We conducted whole genome bisulfite sequencing on peripheral blood from sporadic binocular or monocular congenital cataract patients and cataract-free participants. Results: We found massive differentially methylated regions within the whole genomes between any two groups. Meanwhile, we identified five genes (ACTN4, ACTG1, TUBA1A, TUBA1C, TUBB4B) for the binocular and control groups and TUBA1A for the monocular and control groups as the core differentially methylated region-related genes. The proteins encoded by these core genes are involved in building cytoskeleton and intercellular junctions. Conclusion: Changes in the methylation levels of core genes may disturb the function of cytoskeleton and intercellular junctions, eventually leading to sporadic congenital cataract.

The molecular mechanisms underlying lens fiber elongation

Lens fiber cells are highly elongated cells with complex membrane morphologies that are critical for the transparency of the ocular lens. Investigations into the molecular mechanisms underlying lens fiber cell elongation were first reported in the 1960s, however, our understanding of the process is still poor nearly 50 years later. This review summarizes what is currently hypothesized about the regulation of lens fiber cell elongation along with the available experimental evidence, and how this information relates to what is known about the regulation of cell shape/elongation in other cell types, particularly neurons.

Microtubule configuration and membranous vesicle transport in elongating fiber cells of the rat lens

This study examines the microtubule configuration and its close association with the Golgi complex and Golgi-derived membranous vesicles in elongating fiber cells of the rat lens. Since fiber cells elongate tremendously during lens differentiation, we hypothesize that a microtubule-based motor system exists in the elongating fiber cells for transporting important membrane proteins and organelles to the target regions for cell growth. The newly synthesized membrane proteins are known to be transported from the trans-Golgi network in the form of vesicles to the target plasma membrane. By thin-section TEM, we observed a large number of vesicles of various sizes and shapes randomly distributed throughout the cytoplasm of elongating fiber cells. Both Golgi complex and vesicles exhibited characteristic normal structural features seen in other cell types and thus represented real vesicular organelles in the fiber cells. A large number of microtubules were regularly arranged into bundles parallel to the long axis of fiber cells as examined in both longitudinal and cross-section views. Many of these microtubules were closely associated or in intimate contact with the Golgi complex and vesicles in elongating fiber cells. The microtubule polarity assay revealed that microtubules exhibited a unidirectional polarity for the entire length of fiber cells as examined in both anterior and posterior cortical fiber segments. Namely, the minus end of microtubules was towards the anterior lens pole while the plus end was headed towards the posterior pole. This suggests that multiple molecular motors such as kinesin and dynein are needed for carrying the vesicles to both lens poles, since conventional kinesin is known to transport vesicular organelles towards the plus end whereas cytoplasmic dynein carries them towards the minus end of microtubules. By immunoblot analysis, we indeed detected the presence of both kinesin (120 kD) and dynein (70 kD) in homogenate prepared from lens cortical fibers. Moreover, immunogold TEM demonstrated that the aquaporin 0 (formally MIP26) antibody was localized on the membranous vesicles as well as plasma membranes of the cortical fiber cells. This study suggests that a microtubule-based motor system exists in the lens and plays an important role in transporting membrane proteins such as aquaporin 0 in the vesicles during fiber cell differentiation and elongation.

Structure, development and function of cytoskeletal elements in non-neuronal cells of the human eye

The cytoskeleton, of which the main components in the human eye are actin microfilaments, intermediate filaments and microtubules with their associated proteins, is essential for the normal growth, maturation, differentiation, integrity and function of its cells. These components interact with intra- and extracellular environment and each other, and their profile frequently changes during development, according to physiologic demands, and in various diseases. The ocular cytoskeleton is unique in many ways. A special pair of cytokeratins, CK 3 and 12, has apparently evolved only for the purposes of the corneal epithelium. However, other cytokeratins such as CK 4, 5, 14, and 19 are also important for the normal ocular surface epithelia, and other types may be acquired in keratinizing diseases. The intraocular tissues, which have a relatively simple cytoskeleton consisting mainly of vimentin and simple epithelial CK 8 and 18, differ in many details from extraocular ones. The iris and lens epithelium characteristically lack cytokeratins in adults, and the intraocular muscles all have a cytoskeletal profile of their own. The dilator of the iris contains vimentin, desmin and cytokeratins, being an example of triple intermediate filament expression, but the ciliary muscle lacks cytokeratin and the sphincter of the iris is devoid even of vimentin. Conversion from extraocular-type cytoskeletal profile occurs during fetal life. It seems that posttranslational modification of cytokeratins in the eye may also differ from that of extraocular tissues. So far, it has not been possible to reconcile the cytoskeletal profile of intraocular tissues with their specific functional demands, but many theories have been put forward. Systematic search for cytoskeletal elements has also revealed novel cell populations in the human eye. These include transitional cells of the cornea that may represent stem cells on migration, myofibroblasts of the scleral spur and juxtacanalicular tissue that may modulate aqueous outflow, and subepithelial matrix cells of the ciliary body and myofibroblasts of the choroid that may both participate in accommodation. In contrast to the structure and development of the ocular cytoskeleton, changes that take place in ocular disease have not been analysed systematically. Nevertheless, potentially meaningful changes have already been observed in corneal dystrophies (Meesmann's dystrophy, posterior polymorphous dystrophy and iridocorneal endothelial syndrome), degenerations (pterygium) and inflammatory diseases (Pseudomonas keratitis), in opacification of the lens (anterior subcapsular and secondary cataract), in diseases characterized by proliferation of the retinal pigment epithelium (macular degeneration and proliferative vitreoretinopathy), and in intraocular tumours (uveal melanoma). In particular, upregulation of alpha-smooth muscle actin seems to be a relatively general response typical of spreading and migrating corneal stromal and lens epithelial cells, trabecular cells and retinal pigment epithelial cells.

alpha-Crystallin quaternary structure: molecular basis for its chaperone activity

alpha-Crystallin, the major protein in all vertebrate lenses, functions as a chaperone. In the present analysis, an 'open' micellar structure composed of alpha A subunits is used to simulate chaperoning of partially heat denatured soluble gamma-crystallin. The interaction is both electrostatic and hydrophobic and satisfies experimental evidence for a 1:1 alpha/gamma molar ratio, a doubling of molecular mass and a minimal increase in the dimensions of the complex [J. Biol. Chem. (1994) 269, 13601-13608; Invest. Opthalmol. Vis. Sci. (1995) 36, 311-21]. These data are also in accord with Farahbaksh et al. [Biochemistry (1995) 34, 509-16]; i.e. the bound gamma-crystallin monomers are not in a central cavity, but are separated by alpha A subunits.

Interaction of ATP and lens alpha crystallin characterized by equilibrium binding studies and intrinsic tryptophan fluorescence spectroscopy

alpha-Crystallin, the most prevalent protein in vertebrate lenses, is a high molecular weight aggregate composed of alpha A and alpha B subunits. Evidence is presented that ATP, a major phosphorus metabolite of the lens binds to alpha-crystallin extracted from calf lenses. The following parameters were obtained from equilibrium binding studies conducted at 37 degrees C: binding sites per 400 kDa aggregate = 10 and Ka = 8.1 x 10(3) M-1; and an essentially identical Ka of 7.84 x 10(3) M-1 and 22 binding sites were determined for a 850 kDa aggregate. The cooperativity parameter, alpha H, approximates unity which denotes that the binding of ligand is at independent sites. Binding was not significant at 22 degrees C and was absent at 4 degrees C. The specificity of the binding site for ATP was established by intrinsic tryptophan fluorescence spectroscopy. In the presence of increasing concentrations of ATP (0.05-0.3 mM), tryptophan fluorescence decreases in a concentration dependent manner to a minimum of 0.2 mM above which there is a non-linear response. Quenching of fluorescence was not evident with P(i), AMP or ADP. GTP elicited a minimal quenching of fluorescence only at the highest concentration (0.30 mM). Modulation of both supramolecular organization and lens metabolism is predicted as a consequence of ATP/alpha-crystallin binding.

Regional variations in electrolytes related to resistivity during bovine lens maturation

Little is known regarding the behavior of ions in protein-rich cytoplasm characteristic of lens fiber cells. Resistivity is dependent upon the electrolyte concentration available to conduct an applied current and the mobility of these electrolytes. In the present study, the relative importance of these factors in the increasing cortico-nuclear resistivity gradient reported for both calf and bovine lens homogenates was analysed. Relative ion mobility for regions of the lens was determined by the calculation of the ratio of resistivity of lens homogenates to resistivity of aqueous solutions of freely mobile KCl at the same molarity. The increasing resistivity ratios in the calf cortex, transition zone and nucleus suggest an increasingly impaired ion mobility from the outer to the inner lens regions.

Age-dependent changes in resistivity and electrolytes related to lens development and growth in the rat

Alterations in resistivity measurements of lens homogenates, lens percent water and cation concentrations of sodium and potassium show a complex pattern in the Sprague-Dawley rat during lens development and maturation. During the neonatal period, the data provide evidence for three distinct periods: days 5-12, a pre-critical maturation period (pre-CMP), a steep decline in cation concentration and a minimal change in percent water were accompanied by an expected sharp rise in resistivity; days 12-16, critical maturation period (CMP), a further decrease in ion concentration and water was concomitant with the unexpected observation of no significant change in resistivity; and days 16-30, post-CMP, no significant changes were observed for cation concentrations, percent water, or resistivity. From 30 to 100 days, an adult nuclear maturation period (NMP), a decrease in cation concentration and percent water was reflected in a rise in resistivity. A comparison of 100 and 500 day lenses revealed that the concentrations of Na and K, and percent water are essentially unchanged. The K/Na ratio, which had decreased from an initial value of 5.9 at 5 days, stabilized at approximately 4 by day 100. A comparison of the resistivity measured in both lens homogenates and KCl solutions at identical molar strengths revealed that, for the ages studied, ion concentration and ion mobility play important roles in determining this parameter. The underlying cause for age related variations in lens susceptibility to cataractogenic insult is most likely related to complex changes in composition and resistivity which undoubtedly reflect adjustments in molecular organization. The proposition that the lens is a 'free flowing' syncytium of cells appears unwarranted.

Water self-diffusion in the calf lens

Proton pulsed gradient spin echo (PGSE) nuclear magnetic resonance (NMR) spectroscopy was used to explore the free and restricted non-Brownian nature of lens water self-diffusion in calf lens tissue. At all temperatures investigated the water self-diffusion coefficient (Dw) of the cortical homogenate (25% protein) was 1.6-1.7 times greater than that for the nucleus (42% protein), and 0.3-0.5 times the value of Dw for pure water. The nuclear lens homogenate displayed anomalous temperature dependent water diffusion behavior, i.e. a departure from the smooth monotonic decrease in Dw with decreasing temperature, in the temperature range of 3-5 degrees C. By contrast, no such behavior was observed for cortical homogenate. Analysis of water proton echo attenuation data employing a parallel-plate model of restricted diffusion provided values for the parallel-plate barrier separation and self-diffusion coefficient in the limit of free diffusion. Nuclear material showed a smaller spatially average barrier separation and a significantly stronger barrier separation temperature dependence than cortical material.

The ultrastructure of fiber cells in primate lenses: a model for studying membrane senescence

We have compared the surface morphology of the youngest (cortical) fiber cells with that of the most senescent (nuclear) fiber cells in monkey and baboon crystalline lenses by stereo scanning electron microscopy (SEM) and thick-section stereo transmission electron microscopy (TEM). Both the broad and the narrow faces of the most senescent fiber cells featured distinctive, polygonal areas (domains) of furrowed cell membrane. The domains ranged in size from 2.42 to 8.78 microns2. Stereopair SEM and TEM micrographs demonstrated precisely oriented microvilli measuring approximately 0.14 micron in diameter and ranging in length from 1.27 to 4.65 microns overlying each ridge in the domains. Formation of microvilli on senescent cells has been noted in other types of aging cells but they are imprecisely arranged and their function is unknown. Since every fiber cell remains in a fixed location (relative to other fiber cells) throughout life, the lens provides a unique model to study structure-function relationships of senescent microvilli in situ. The discovery of an age-related elaboration of numerous microvilli on senescent fiber cells of noncataractous lenses invalidates the currently accepted theory that close, parallel apposition of the broad faces of lens fiber cells is necessary for the lens to be transparent.

Vinculin in cultured bovine lens-forming cells

The distribution and organization of vinculin in bovine lens-forming cells was studied in short- and long-term cultures by using monospecific antibodies and immunofluorescence microscopy. In the epithelioid cells, originating from the epithelial cell layer of the anterior capsule, vinculin was located at contact sites of the adjacent cells. In the elongated cells, representing the cortical fiber cells, vinculin could be seen exclusively as numerous patches at the substratum-facing side of the cells. In these cells, no lateral foci of vinculin, corresponding to cell-cell contact sites, were discernible. The results show that cells originating from different parts of the bovine lens display divergent vinculin locations, probably reflecting altered cytoskeletal organization and cell-cell interactions during differentiation.

Chicken embryo lens cultures mimic differentiation in the lens

Embryonic chicken lenses, which had been disrupted by trypsin, were grown in culture. These cultures mimic lens development as it occurred in vivo, forming lens-like structures known as lentoids. Using a variety of techniques including electron microscopic analysis, autoradiography, immunofluorescence, and polyacrylamide gel electrophoresis, it was shown that the lentoid cells had many characteristics in common with the differentiated cells of the intact lens, the elongated fiber cells. These characteristics included a shut off of DNA synthesis, a loss of cell organelles, an increase in cell volume, an increase in delta-crystallin protein, and the development of extensive intercellular junctions. The cultures began as a simple epithelial monolayer but then underwent extensive morphogenesis as they differentiated. This morphogenesis involved three distinctive morphological types which appeared in sequence as an epithelial monolayer of polygonal shaped cells with pavement packing, elongated cells oriented end to end, and the multilayered, multicellular lentoids. These distinct morphological stages of differentiation in culture mimic morphogenesis as it occurs in the lens.

Immunofluorescent localization of two intrinsic membrane polypeptides in adult human lenses

Two major intrinsic membrane polypeptides of molecular weights 22K and 26K have been isolated and antisera for each prepared against highly purified preparations. The lack of reactivity of these antibodies in several other tissues suggests that they are unique to the lens. These antisera were used for localization of these polypeptides in adult human lenses by indirect immunofluorescent staining. Neither of the polypeptides is found in the epithelial cells; however those cells commencing differentiation show some fluorescent staining. The elongating fiber cells of the bow region show cytoplasmic staining for both 22K and 26K. This may reflect their sites of synthesis. In this region the species of 22K studies showed no localization in the membrane; however, 26K is concentrated at the membrane as evidenced by the intense band of fluorescent staining in this region. In the lens inner cortical region, there is a loss of cytoplasmic staining and both polypeptides appear to be membrane bound. This redistribution of the membrane polypeptides occurring in the inner cortex is at the site of considerable lens fiber contour alterations.