Embryonic appearance of alpha, beta, and gamma crystallins in the periodic albinism (ap) mutant of Xenopus laevis.

The appearance of the crystallins during lens development in the periodic albinism (ap/ap) mutant of Xenopus laevis has been studied. Using antibodies specific for total crystallins, alpha + beta crystallins, and gamma crystallins in the immunofluorescence technique, the first positive reaction for all could be demonstrated in the Nieuwkoop-Faber Stage 31 lens rudiment. The antibody to alpha + beta crystallins exhibited differences in intensity from cell to cell in the early rudiment, while the reaction to the other antibodies was uniform throughout the rudiment. As lens differentiation progressed, immunofluorescence was restricted in all cases to the lens fiber area, up to and including Nieuwkas positive, however, for total lens crystallins. These results are at variance with earlier studies on lens development and the crystallins in wildtype (+/+) X. laevis, where a positive reaction for gamma and total crystallins could be detector total lens crystallins. That this divergence in the mutant is due to a pleiotropic effect or directly to the inductive failure of the endomesoderm to initiate melanogenesis, is discussed.     

Embryonic Appearance of α, β, and γ Crystallins in the Periodic Albinism (ap) Mutant of Xenopus laevis

The appearance of the crystallins during lens development in the periodic albinism (a^p/a^p) mutant of Xenopus laevis has been studied. Using antibodies specific for total crystallins, α+β crystallins, and γ crystallins in the immunofluorescence technique, the first positive reaction for all could be demonstrated in the Nieuwkoop-Faber Stage 31 lens rudiment. The antibody to α+β crystallins exhibited differences in intensity from cell to cell in the early rudiment, while the reaction to the other antibodies was uniform throughout the rudiment. As lens differentiation progressed, immunofluorescence was restricted in all cases to the lens fiber area, up to and including Nieuwkoop-Faber Stage 45. The lens epithelium of the one-year-old adult a^p/a^p was positive, however, for total lens crystallins.
These results are at variance with earlier studies on lens development and the crystallins in wild-type (+/+) X. laevis , where a positive reaction for y and total crystallins could be detected earlier, and in the lens epithelium of Nieuwkoop-Faber Stage 41 embryos for total lens crystallins. That this divergence in the mutant is due to a pleiotropic effect or directly to the inductive failure of the endomesoderm to initiate melanogenesis, is discussed.     

The human crystallin gene families

Crystallins are the abundant, long-lived proteins of the eye lens. The major human crystallins belong to two different superfamilies: the small heat-shock proteins (α-crystallins) and the βγ-crystallins. During evolution, other proteins have sometimes been recruited as crystallins to modify the properties of the lens. In the developing human lens, the enzyme betaine-homocysteine methyltransferase serves such a role. Evolutionary modification has also resulted in loss of expression of some human crystallin genes or of specific splice forms. Crystallin organization is essential for lens transparency and mutations; even minor changes to surface residues can cause cataract and loss of vision.     

Solution properties of γ‐crystallins: Compact structure and low frictional ratio are conserved properties of diverse γ‐crystallins

γ‐crystallins are highly specialized proteins of the vertebrate eye lens where they survive without turnover under high molecular crowding while maintaining transparency. They share a tightly folded structural template but there are striking differences among species. Their amino acid compositions are unusual. Even in mammals, γ‐crystallins have high contents of sulfur‐containing methionine and cysteine, but this reaches extremes in fish γM‐crystallins with up to 15% Met. In addition, fish γM‐crystallins do not conserve the paired tryptophan residues found in each domain in mammalian γ‐crystallins and in the related β‐crystallins. To gain insight into important, evolutionarily conserved properties and functionality of γ‐crystallins, zebrafish (Danio rerio) γM2b and γM7 were compared with mouse γS and human γD. For all four proteins, far UV CD spectra showed the expected β‐sheet secondary structure. Like the mammalian proteins, γM7 was highly soluble but γM2b was much less so. The heat and denaturant stability of both fish proteins was lower than either mammalian protein. The ability of full‐length and truncated versions of human αB‐crystallin to retard aggregation of the heat denatured proteins also showed differences. However, when solution behavior was investigated by sedimentation velocity experiments, the diverse γ‐crystallins showed remarkably similar hydrodynamic properties with low frictional ratios and partial specific volumes. The solution behavior of γ‐crystallins, with highly compact structures suited for the densely packed environment of the lens, seems to be highly conserved and appears largely independent of amino acid composition.     

Crystallins in the differentiation and regeneration processes of the crystalline lens in amphibia

The published and authors' data have been summarized on (1) the spectrum and properties of crystallins in different amphibian species, (2) localization and synthesis of crystallins in different cellular compartments of the adult amphibian lens, (3) dynamics of crystallin formation during embryogenesis and (4) lens regeneration from tissues of the larval and adult amphibian eyes. The necessity of more detailed studies of crystallin synthesis during embryogenesis and lens regeneration using molecular biological and biochemical methods is stressed. The significance of this approach is illustrated by the pioneering data of Soviet scientists on crystallin polypeptides and corresponding mRNAs in development of Rana temporaria obtained with the use of DNA-RNA hybridization and immunoelectroblotting.     

Crystallin distribution patterns in concentric layers from toad eye lenses

Protein distribution patterns across eye lenses from the Asiatic toad Bufo gargarizans were investigated and individual crystallin classes characterised. Special fractionation that follows the growth mode of the lens was used to yield nine fractions corresponding to layers laid down at different chronological (developmental) stages. Proportions of soluble and insoluble crystallins within each fraction were measured by Bradford assay. Water‐soluble proteins in all fractions were separated by size‐exclusion HPLC and constituents of each class further characterised by electrophoresis, RP‐HPLC and MS analysis. In outer lens layers, α‐crystallin is the most abundant soluble protein but is not found in soluble proteins in the lens centre. Water‐soluble β‐crystallins also decrease from their highest level in the outer lens to negligible mounts in the central lens. The proportion of soluble γ‐crystallin increases significantly towards the lens centre where this is the only soluble protein present. Insoluble protein levels increase significantly towards the lens centre. In B. gargarizans lenses, as with other anurans, the predominant water‐soluble protein class is γ‐crystallin. No taxon‐specific crystallins were found. The relationship between the protein distribution patterns and the functional properties of the lens this species is discussed.     

Comparative study of the crystallin supramolecular structure in the carp, frog, and rat lenses by small-angle roentgen ray scattering

The supramolecular structure of crystallins in intact ocular lenses of carp, frog and rat as well as in the interior (nuclear) and outer (cortical) parts of these lenses was studied by the small-angle X-ray scattering method. The results show that the supramolecular structure of crystallins substantially varies both in lenses of different vertebrate species and in various parts of the same lens. In carp lens and in the cortical part of rat lens, crystallins have an ordered supramolecular structure, as indicated by a small-angle X-ray diffraction maximum in the region of Bragg distances 15-20 nm, whereas in frog lens and in the nuclear part of rat lens, the supramolecular structure of these proteins is disordered. The power-law X-ray scattering by rat lens nucleus may be evidence of fractal structures in the lens. A comparison of these results with literary data indicates that there is no obvious correlation between the type of supramolecular structure of crystallins and their polypeptide composition in lenses of different vertebrate species. The results suggest that the supramolecular ordering (short-range order) of crystallins is not a necessary condition for lens transparency.     

Corneal crystallins and the development of cellular transparency

Past studies have established that the cornea like the lens abundantly expresses a few water-soluble enzyme/proteins in a taxon specific fashion. Based on these similarities it has been proposed that the lens and the cornea form a structural unit, the 'refracton', that has co-evolved through gene sharing to maximize light transmission and refraction to the retina. Thus far, the analogy between corneal crystallins and lens crystallins has been limited to similarities in the abundant expression, with few reports concerning their structural function. This review covers recent studies that establish a clear relationship between expression of corneal crystallins and light scattering from corneal stromal cells, i.e. keratocytes, that support a structural role for corneal crystallins in the development of transparency similar to that of lens crystallins that would be consistent with the 'refracton' hypothesis.     

Immunochemical markers of embryonic lens differentiation in Rana temporaria. I. Composition and properties of water-soluble lens antigens]

Antisera were obtained to the total extract and individual electrophoretic fractions of lens proteins: alpha-, beta-, gamma1- and gamma2-crystallins. The crystallins under study are immunochemically heterogenous: each class of lens proteins contains 2--4 antigens. Using the indirect method of fluorescent antibodies, it was established that the appearance of crystallins during development coincided with the onset of formation of the presumptive lens fibers. No crystallins were found in the lens placode and early lens vesicle. gamma-Crystallins appear later than the other lens proteins and are characteristic, mainly, for the lens fibers; at the advanced stages of organogenesis gamma-crystallins are regularly found in the epithelial cells of the developing lens as well.     

Evolution of crystallins for a role in the vertebrate eye lens

The camera eye lens of vertebrates is a classic example of the re‐engineering of existing protein components to fashion a new device. The bulk of the lens is formed from proteins belonging to two superfamilies, the α ‐crystallins and the β γ ‐crystallins. Tracing their ancestry may throw light on the origin of the optics of the lens. The α ‐crystallins belong to the ubiquitous small heat shock proteins family that plays a protective role in cellular homeostasis. They form enormous polydisperse oligomers that challenge modern biophysical methods to uncover the molecular basis of their assembly structure and chaperone‐like protein binding function. It is argued that a molecular phenotype of a dynamic assembly suits a chaperone function as well as a structural role in the eye lens where the constraint of preventing protein condensation is paramount. The main cellular partners of α ‐crystallins, the β ‐ and γ ‐crystallins, have largely been lost from the animal kingdom but the superfamily is hugely expanded in the vertebrate eye lens. Their structures show how a simple Greek key motif can evolve rapidly to form a complex array of monomers and oligomers. Apart from remaining transparent, a major role of the partnership of α ‐crystallins with β ‐ and γ ‐crystallins in the lens is to form a refractive index gradient. Here, we show some of the structural and genetic features of these two protein superfamilies that enable the rapid creation of different assembly states, to match the rapidly changing optical needs among the various vertebrates.     

Gene sharing, lens crystallins and speculations on an eye/ear evolutionary relationship

The crystallins comprise 80–90% of the water-soluble proteinsof the transparent, cellular, refractive eye lens and are responsiblefor its optical properties. Comparative studies have establishedthat the crystallins are surprisingly diverse and often differamong species in a taxon-specific fashion. In general, the crystallinsare derived from or identical to metabolic enzymes or stress(small heat shock) proteins that are expressed to a lesser extentin other tissues where they have non-refractive roles. We callthe phenomenon of having the small heat shock protein or enzymeand lens crystallin encoded in the identical gene "gene sharing";examples include small heat shock protein/     

Crystallin Expression in the TVI Cell Line

The TVI cell line, derived from dorsal iris cells of adult newts ( Notophthalmus viridescens ), was investigated for the presence of crystallins. Since there is reason to believe that iris epithelial cells are the main sources of this cell line and since iris epithelial cells are known to convert into lens cells in primary cultures, it is possible that TVI cells also possess the capacity to synthesize crystallins, those proteins characteristic of lens cells. It is also possible, however, that the large number of passages gone through by TVI cells in the past has eliminated such differentiated synthetic capacity expressed in earlier generations. Our immunoelectrophoresis studies reveal the presence of small amounts of α and β crystallins, and the absence of γ crystallins in TVI cells. Furthermore, immunofluorescence observations demonstrate that a small number of cells comparable to lens epithelial cells in crystallin composition and morphology are present in TVI cultures. In view of the fact that in the amphibian lens, epithelial cells which retain proliferative activity accumulate α and β crystallins but not γ crystallins, while fiber cells which are devoid of proliferative activity accumulate all three classes of crystallins, the present results suggest that the TVI cell line has lost the capacity to maintain lens fiber cells, which are known to be present in primary culture of iris epithelial cells.     

Lactate Dehydrogenase Like Crystallin: A Potentially Protective Shield for Indian Spiny-Tailed Lizard (Uromastyx hardwickii) Lens Against Environmental Stress?

Taxon specific lens crystallins in vertebrates are either similar or identical with various metabolic enzymes. These bifunctional crystallins serve as structural protein in lens along with their catalytic role. In the present study, we have partially purified and characterized lens crystallin from Indian spiny-tailed lizard (Uromastyx hardwickii). We have found lactate dehydrogenase (LDH) activity in lens indicating presence of an enzyme crystallin with dual functions. Taxon specific lens crystallins are product of gene sharing or gene duplication phenomenon where a pre-existing enzyme is recruited as lens crystallin in addition to structural role. In lens, same gene adopts refractive role in lens without modification or loss of pre-existing function during gene sharing phenomenon. Apart from conventional role of structural protein, LDH activity containing crystallin in U. hardwickii lens is likely to have adaptive characteristics to offer protection against toxic effects of oxidative stress and ultraviolet light, hence justifying its recruitment. Taxon specific crystallins may serve as good models to understand structure–function relationship of these proteins.     

The role of macromolecular crowding in the evolution of lens crystallins with high molecular refractive index

Crystallins are present in the lens at extremely high concentrations in order to provide transparency and generate a high refractive power of the lens. The crystallin families prevalent in the highest density lens tissues are γ-crystallins in vertebrates and S-crystallins in cephalopods. As shown elsewhere, in parallel evolution, both have evolved molecular refractive index increments 5-10% above those of most proteins. Although this is a small increase, it is statistically very significant and can be achieved only by very unusual amino acid compositions. In contrast, such a molecular adaptation to aid in the refractive function of the lens did not occur in crystallins that are preferentially located in lower density lens tissues, such as vertebrate α-crystallin and taxon-specific crystallins. In the current work, we apply a model of non-interacting hard spheres to examine the thermodynamic contributions of volume exclusion at lenticular protein concentrations. We show that the small concentration decrease afforded by the higher molecular refractive index increment of crystallins can amplify nonlinearly to produce order of magnitude differences in chemical activities, and lead to reduced osmotic pressure and the reduced propensity for protein aggregation. Quantitatively, this amplification sets in only at protein concentrations as high as those found in hard lenses or the nucleus of soft lenses, in good correspondence to the observed crystallin properties in different tissues and different species. This suggests that volume exclusion effects provide the evolutionary driving force for the unusual refractive properties and the unusual amino acid compositions of γ-crystallins and S-crystallins.     

Protein oxidation and loss of protease activity may lead to cataract formation in the aged lens

Over 95% of the dry mass of the eye lens consists of specialized proteins called crystallins. Aged lenses are subject to cataract formation, in which damage, cross-linking, and precipitation of crystallins contribute to a loss of lens clarity. Cataract is one of the major causes of blindness, and it is estimated that over 50,000,000 people suffer from this disability. Damage to lens crystallins appears to be largely attributable to the effects of UV radiation and/or various active oxygen species (oxygen radicals, ¹O₂, H₂O₂, etc.). Photooxidative damage to lens crystallins is normally retarded by a series of antioxidant enzymes and compounds. Crystallins which experience mild oxidative damage are rapidly degraded by a system of lenticular proteases. However, extensive oxidation and cross-linking severely decrease proteolytic susceptibility of lens crystallins. Thus, in the young lens the combination of antioxidants and proteases serves to prevent crystallin damage and precipitation in cataract formation. The aged lens, however, exhibits diminished antioxidant capacity and decreased proteolytic capabilities. The loss of proteolytic activity may actually be partially attributable to oxidative damage which proteases (like any other protein)_can sustain. We propose that the rate of crystallin damage increases as antioxidant capacity declines with age. The lower protease activity of aged lens cells may be insufficient to cope with such rates of crystallin damage, and denatured crystallins may begin to accumulate. As the concentration of oxidatively denatured crystallins rises, cross-linking reactions may produce insoluble aggregates which are refractive to protease digestion. Such a scheme could explain many events which are known to contribute to cataract formation, as well as several which have appeared to be unrelated. This hypothesis is also open to experimental verification and intervention.     

Ubiquitous lens alpha-, beta-, and gamma-crystallins accumulate in anuran cornea as corneal crystallins

Corneal epithelium is known to have high levels of some metabolic enzymes such as aldehyde dehydrogenase in mammals, gelsolin in zebrafish, and alpha-enolase in several species. Analogous to lens crystallins, these enzymes and proteins are referred to as corneal crystallins, although their precise function is not established in any species. Although it is known that after lentectomy, the outer cornea undergoes transdifferentiation to regenerate a lens only in anuran amphibians, major proteins expressed in an anuran cornea have not been identified. This study therefore aimed to identify the major corneal proteins in the Indian toad (Bufo melanostictus) and the Indian frog (Rana tigrina). Soluble proteins of toad and frog corneas were resolved on two-dimensional gels and identified by matrix-assisted laser desorption ionization time-of-flight/time-of-flight and electrospray ionization quadrupole time-of-flight. We report that anuran cornea is made up of the full complement of ubiquitous lens alpha-, beta-, and gamma-crystallins, mainly localized in the corneal epithelium. In addition, some taxon-specific lens crystallins and novel proteins, such as alpha- or beta-enolase/tau-crystallin, were also identified. Our data present a unique case of the anuran cornea where the same crystallins are used in the lens and in the cornea, thus supporting the earlier idea that crystallins are essential for the visual functions of the cornea as they perform for the lens. High levels of lens alpha-, beta-, and gamma-crystallins have not been reported in the cornea of any species studied so far and may offer a possible explanation for their inability to regenerate a lens after lentectomy. Our data that anuran cornea has an abundant quantity of almost all the lens crystallins are consistent with its ability to form a lens, and this connection is worthy of further studies.     

Trigonella foenum graecum seed powder protects against histopathological abnormalities in tissues of diabetic rats

Premature visual impairment due to lens opacification is a debilitating characteristic of untreated diabetes. Lens opacification is primarily due to the insolubilization of crystallins, proteins essential for lens optical properties, and recent studies have suggested that a major cause of this insolubilization may be the unregulated proteolysis of crystallins by calpains. These are intracellular cysteine proteases whose activation requires the presence of calcium (Ca2+) and elevated levels of lens Ca2+ is a condition associated with both diabetic cataractogenesis and other forms of the disorder. A number of calpains have been identified in the lens, including calpain 2, calpain 10 and two isozymes of calpain 3: Lp82 and Lp85. The use of animal hereditary cataract models have suggested that calpain 2 and/or Lp82 may be the major calpains involved in murine cataractogenesis with contributions from calpain 10 and Lp85. However, calpain 2 appears to be the major calpain involved in murine diabetic cataractogenesis and the strongest candidate of the calpains for a role in human types of cataractogenesis. Here, we present an overview of recent evidence on which these observations are based with an emphasis on the ability of calpains to proteolyse lens crystallins and calpain structural features, which appear to be involved in the Ca2+-mediated activation of these enzymes.     

Metabolism of crystallin fragments in cell-free extracts of bovine lens: effects of ageing and oxygen free-radicals.

1. The ability of cell-free preparations from bovine lens to degrade fragments of alpha-crystallin has been studied. Crystallin fragments, produced by either chemical cleavage with cyanogen bromide or prolonged treatment with H2O2 and Cu2+ to produce hydroxyl radicals, were labelled with 125I and incubated with preparations obtained from lenses from animals of different age. 2. Results showed that the ability of the preparations obtained from the lens cores (the innermost part of the lens composed of enucleated non-dividing cells incapable of protein synthesis) to degrade crystallin fragments decreased with animal age. No such age-related correlation was obtained with preparations obtained from the cortex (the outer region of the lens surrounding the core). 3. The effect of incubation of the various lenticular preparations with H2O2 and Cu2+ on subsequent ability to catabolise crystallin fragments was also examined. Preparations from the oldest lenses were found to be the least resistant to free-radical attack. 4. The relative susceptibility of the crystallins and non-lenticular proteins to H2O2/Cu(2+)-mediated free-radical attack was examined. Not only were the various crystallins (alpha, beta and gamma) far more resistant to cleavage under these conditions, they also protected the non-lenticular proteins from free-radical-mediated attack. The comparative resistance of the crystallins to attack and their ability to protect other proteins appeared to be dependent on their structural integrity as prior denaturation with acid and/or cleavage with cyanogen bromide eliminated these properties. 5. It is suggested that crystallins (which show sequence homology to some heat-shock proteins) possess homeostatic functions which could protect other proteins (e.g. proteases) from certain forms of free-radical-mediated damage; crystallins may therefore be important in ageing in general where aberrant polypeptides accumulate.     

The appearance of alpha-crystallin in relation to cell cycle phase in the embryonic mouse lens

Specific protein synthesis in the embryonic mouse lens was studied by immunofluorescence with antisera to adult mouse lens or crystallin fractions. Positive reactions were first detected in a few cells of the lens cup 18-24 hr after contact between optic vesicle and presumptive lens ectoderm had been established. During formation of the lens vesicle a rapidly increasing fraction of cells produced crystallins. At the time of detachment of the vesicle from the surface all cells of its posterior wall showed immunofluorescence. After fiber elongation became distinct cells of the anterior epithelium began to fluoresce and shortly afterwards the entire rudiment produced crystallins. The early reactions were due entirely to the presence of alpha-crystallin. Reactions were restricted to the lens. Thus, in the mouse as in other species crystallins were detectable by immunofluorescence in vivo only after lens morphogenesis was well underway and only in the lens rudiment itself. Cells first synthesizing crystallins always had an elongated shape and their nuclei were in a basal position. A few hours later mitotic cells displayed fluorescence. Taking into account earlier found relations between cell morphology and cell cycle phase, this indicates that alpha-crystallin is first demonstrable in the S-or early G-2 phase of the cell cycle, and that the start of its synthesis does not preclude continued cell replication. It is interesting that the cellular location, cell cycle phase, and developmental stage, in which crystallins first appear, are comparable in mouse and chick embryo. Yet, entirely different proteins are involved: alpha-crystallin in the first, delta-crystallin in the latter. Implications of this for our understanding of lens induction are discussed.     

Solution properties of γ‐crystallins: Hydration of fish and mammal γ‐crystallins

Lens γ crystallins are found at the highest protein concentration of any tissue, ranging from 300 mg/mL in some mammals to over 1000 mg/mL in fish. Such high concentrations are necessary for the refraction of light, but impose extreme requirements for protein stability and solubility. γ‐crystallins, small stable monomeric proteins, are particularly associated with the lowest hydration regions of the lens. Here, we examine the solvation of selected γ‐crystallins from mammals (human γD and mouse γS) and fish (zebrafish γM2b and γM7). The thermodynamic water binding coefficient B₁ could be probed by sucrose expulsion, and the hydrodynamic hydration shell of tightly bound water was probed by translational diffusion and structure‐based hydrodynamic boundary element modeling. While the amount of tightly bound water of human γD was consistent with that of average proteins, the water binding of mouse γS was found to be relatively low. γM2b and γM7 crystallins were found to exhibit extremely low degrees hydration, consistent with their role in the fish lens. γM crystallins have a very high methionine content, in some species up to 15%. Structure‐based modeling of hydration in γM7 crystallin suggests low hydration is associated with the large number of surface methionine residues, likely in adaptation to the extremely high concentration and low hydration environment in fish lenses. Overall, the degree of hydration appears to balance stability and tissue density requirements required to produce and maintain the optical properties of the lens in different vertebrate species.