Biochemical and immunological studies of lentoid formation in cultures of embryonic chick neural retina and day-old chick lens epithelium

During long-term cell culture of 8-day embryonic chick neural retina, lentoid bodies containing lens crystallins are developed. Although very low levels of crystallin can be detected in the embryonic neural retina, gross synthesis of each major crystallin class (α, anodal β, cathodal β, and δ) begins only after 12–16 days in culture. This occurs at least 10 days before lentoid bodies can be distinguished by eye. The concentration of each crystallin class was determined during lentoid development in cultures of both neural retina and lens epithelium. The proportions of crystallins in lentoid-containing cultures do not resemble those of embryonic lens fibres. Comparisons between two chick strains (N and Hy-1) differing in their growth rates revealed several differences in the crystallin compositions of lentoid bodies. These differences imply independent quantitative regulation for most or all of the crystallins.     

Physicochemical characterization of a crystallin from the squid lens and its comparison with vertebrate lens crystallins

A crystallin was isolated from the homogenate of the Squid (Loligo pealii) lens by gel filtration on a Sepharose CL-6B (2.5 X 170 cm) column. Biochemical characterization showed it is a dimeric protein with a molecular weight of (5.1 +/- 0.4) X 10(4) and a Stokes' radius of 26A. Electrophoresis on a cellulose acetate membrane indicated it is a basic protein with an isoelectric point higher than 8.6. High resolution two-dimensional gel in 8 M urea/2% NP-40 resolved this crystallin into 6 charge isomers, each with a major subunit of molecular weight 29,000 daltons and a minor subunit of 27,000 daltons in a molar ratio of 3:1. The extreme susceptibility of the protein to denaturation and precipitation even at low temperature hampered further characterization of this crystallin under nondenaturing conditions. Amino acid analysis indicated it contains an unusually high content of methionine (12.8 mol%) which may have some bearing on the instability of this crystallin in vitro. Biochemical comparison of the squid crystallin with mammalian lens crystallins shows that it is a crystallin distinguishable from all reported vertebrate lens crystallins. A detailed study of this protein may shed light on the evolution of lens crystallins in general.     

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.     

Evolution of crystallins: expression of lens-specific proteins in the blind mammals mole (Talpa europaea) and mole rat (Spalax ehrenbergi)

The mole (Talpa europaea; Insectivora) and the mole rat (Spalax ehrenbergi; Rodentia) both have degenerated eyes as a convergent adaptation to subterranean life. The rudimentary eye lenses of these blind mammals no longer function in a visual process. The crystallin genes, which display a lens-specific expression pattern, were studied in these blind mammals and in related species with normal eyes by hybridizing their genomic DNAs with probes obtained from cDNA clones for alpha A-, alpha B-, and beta Bp-crystallins from calf and gamma 3- crystallin from the rat. For all crystallin genes examined, the hybridization signals of mole and mole rat genomic DNA were comparable, respectively, with those of shrew and of rat and mouse, normal-vision representatives of the orders Insectivora and Rodentia. The expression of the crystallins at the protein level was tested by using antiserum specific for alpha-crystallin in immunofluorescence reactions on lens sections of mole and mole rat eyes and by using antisera against the beta- and gamma-crystallins on sections of the mole eye. All antisera gave positive fluorescence reactions exclusively with lens tissue of these blind mammals, indicating that the crystallins are still normally expressed despite the fact that these lenses have had no function in a visual process in these mammals for at least many million years. These findings apparently imply that some unknown selective advantage has conserved the crystallin genes and their expression after the loss of normal function of the lenses.      

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.     

Non-oxidative modification of lens crystallins by kynurenine: a novel post-translational protein modification with possible relevance to ageing and cataract

In humans, the crystallin proteins of the ocular lens become yellow-coloured and fluorescent with ageing. With the development of senile nuclear cataract, the crystallins become brown and additional fluorophores are formed. The mechanism underlying crystallin colouration is not known but may involve interaction with kynurenine-derived UV filter compounds. We have recently identified a sulphur-linked glutathionyl-3-hydroxykynurenine glucoside adduct in the lens and speculated that kynurenine may also form adducts with GSH and possibly with nucleophilic amino acids of the crystallins (e.g. Cys). Here we show that kynurenine modifies calf lens crystallins non-oxidatively to yield coloured (365 nm absorbing), fluorescent (Ex 380 nm/Em 450-490 nm) protein adducts. Carboxymethylation and succinylation of crystallins inhibited kynurenine-mediated modification by approx. 90%, suggesting that Cys, Lys and possibly His residues may be involved. This was confirmed by showing that kynurenine formed adducts with GSH as well as with poly-His and poly-Lys. NMR studies revealed that the novel poly-Lys-kynurenine covalent linkage was via the epsilon-amino group of the Lys side chain and the betaC of the kynurenine side chain. Analysis of tryptic peptides of kynurenine-modified crystallins revealed that all of the coloured peptides contained either His, Cys or an internal Lys residue. We propose a novel mechanism of kynurenine-mediated crystallin modification which does not require UV light or oxidative conditions as catalysts. Rather, we suggest that the side chain of kynurenine-derived lens UV filters becomes deaminated to yield an alpha,beta-unsaturated carbonyl which is highly susceptible to attack by nucleophilic amino acid residues of the crystallins. The inability of the lens fibre cells to metabolise their constituent proteins results in the accumulation of coloured/fluorescent crystallins with age.     

A second polymorphic lens crystallin (LEN-2) in the mouse: Genetic and biochemical analysis of LEN-1 and LEN-2

Two electrophoretic polymorphisms affecting lens crystallins, designated LEN-1 and LEN-2, have been discovered among inbred strains of mice. Analysis by isoelectric focusing demonstrated that both crystallins are monomeric proteins with isoelectric points at or above pH 7. Both proteins eluted in the low molecular weight (LM) fraction upon Sephadex G-200 gel filtration but LEN-2 was shown to be larger than LEN-1 by G75SF gel filtration and denaturing gel electrophoresis. Linkage analysis demonstrated that the genes encoding LEN-1 and LEN-2 assort independently. Amino acid analysis of the allelic products of the two genes revealed that genetic variants of each respective crystallin were very similar in amino acid compositions but that LEN-1 and LEN-2 were dissimilar crystallins.This research was sponsored in part by the Office of Health and Environmental Research, U.S. Department of Energy, under Contract DE-AC05-840R21400 with the Martin Marietta Energy Systems, Inc.     

Crystallins of the octopus lens. Recruitment from detoxification enzymes.

The eye lens crystallins of the octopus Octopus dofleini were identified by sequencing abundant proteins and cDNAs. As in squid, the octopus crystallins have subunit molecular masses of 25-30 kDa, are related to mammalian glutathione S-transferases (GST), and are encoded in at least six genes. The coding regions and deduced amino acid sequences of four octopus lens cDNAs are 75-80% identical, while their non-coding regions are entirely different. Deduced amino acid sequences show 52-57% similarity with squid GST-like crystallins, but only 20-25% similarity with mammalian GST. These data suggest that the octopus and squid lens GST-like crystallin gene families expanded after divergence of these species. Northern blot hybridization indicated that the four octopus GST-like crystallin genes examined are lens-specific. Lens extracts showed about 40 times less GST activity using 1-chloro-2,4-dinitrobenzene as substrate than liver extracts of the octopus, indicating that the major GST-like crystallins are specialized for a lens structural role. A prominent 59-kDa crystallin polypeptide, previously observed in octopus but not squid and called omega-crystallin (Chiou, S.-H. (1988) FEBS Lett. 241, 261-264), has been identified as an aldehyde dehydrogenase. Since cytoplasmic aldehyde dehydrogenase is a major protein in elephant shrew lenses (eta-crystallin; Wistow, G., and Kim, H. (1991) J. Mol. Evol. 32, 262-269) the octopus aldehyde dehydrogenase crystallin provides the first example of a similar enzyme-crystallin in vertebrates and invertebrates. The use of detoxification stress proteins (GST and aldehyde dehydrogenase) as cephalopod crystallins indicates a common strategy for recruitment of enzyme-crystallins during the convergent evolution of vertebrate and invertebrate lenses. For historical reasons we propose that the octopus GST-like crystallins, like those of the squid, are called S-crystallins.     

Lens proteomics: analysis of rat crystallins when lenses are exposed to dexamethasone

To identify glucocorticoid induced cataract (GIC)-specific modified crystallins and related changes, we analyzed rat crystallins and related changes in lenses exposed to dexamethasone (Dex). To carry out proteomics analyses, we separated soluble lens proteins with two-dimensional electrophoresis (2-DE) and modified crystallins were analyzed with matrix assisted laser desorption/ionization time-of-flight tandem mass spectrometry (MALDI-TOF-MS/MS). Related changes in mRNA, protein levels and morphological and functional changes of modified crystallins were also determined. Measured masses (except for γD-crystallin as the larger and cross-link form), the isoelectric points (PIs; except for βB3-crystallin as the alkalinization form) and amino acid sequences of all known rat crystallins matched previously reported data. Analysis by 2-DE indicated that αA, αB, βB3 and γD increased when lenses were exposed to 5 μM Dex; βA4 increased when lenses were exposed to 1 μM Dex and the five proteins that had the highest expressional trend were identical with the results of Q-PCR. βA3/A1 crystallin (expressional trend identical with results of Q-PCR) and the serum albumin precursor gradually disappeared when exposed to 1-50 μM Dex. Results of Western blotting, immunohistochemistry or fluorescence analysis showed that αA and αB increased most when exposed to 5 μM Dex and βA1/A3 and KI-67 decreased obviously when exposed to 1-50 μM Dex. Electron microscopy showed that the condition of the lens was better when lenses were exposed to 5 μM Dex than at other levels and cracks between the fiber cells became larger when lenses were exposed to 1-50 μM Dex. A chaperone role of α-crystallin protecting heated catalase (CAT) and the activity of superoxide dismutase (SOD), glutathione (GSH), and caspase-3 were highest when exposed to 5 μM Dex. Moreover, αA-crystallins were associated with increased phosphorylation (PI decreased). In conclusion, the proteomics analysis and related changes of rat crystallins when lenses were exposed to Dex in this study will be useful for comparison with normal lens proteins and GIC. We also provided a mechanism for GIC from a proteomics aspect based on the in vitro model.     

Modifications of human betaA1/betaA3-crystallins include S-methylation, glutathiolation, and truncation

Disulfide bonding of lens crystallins contributes to the aggregation and insolubilization of these proteins that leads to cataract. A high concentration of reduced glutathione is believed to be key in preventing oxidation of crystallin sulfhydryls to form disulfide bonds. This protective role is decreased in aged lenses because of lower glutathione levels, especially in the nucleus. We recently found that human gamma-crystallins undergo S-methylation at exposed cysteine residues, a reaction that may prevent disulfide bonding. We report here that betaA1/A3-crystallins are also methylated at specific cysteine residues and are the most heavily methylated of the human lens crystallins. Among the methylated sites, Cys 64, Cys 99, and Cys 167 of betaA1-crystallin, methylation at Cys 99 is highest. Cys 64 and Cys 99 are also glutathiolated, even in a newborn lens. These post-translational modifications of the exposed cysteines may be important for maintaining the crystallin structure required for lens transparency. Previously unreported N-terminal truncations were also found.     

Comparative analysis of crystallins and lipids from the lens of Antarctic toothfish and cow

Animal model systems of senile cataract and lens crystallin stability are essential to understand the complex nature of lens transparency. Our aim in this study was to assess the long-lived Antarctic toothfish Dissostichus mawsoni (Norman) as a model system to understand long-term lens clarity in terms of solubility changes that occur to crystallins. We compared the toothfish with the mammalian model cow lens, dissecting each species’ lens into a cortex and nuclear region. In addition to crystallin distribution, we also assayed fatty acid (FA) composition by negative ion electrospray ionization mass spectrometry (ESI-MS). The majority of toothfish lens crystallins from cortex (90.4%) were soluble, whereas only a third (31.8%) from the nucleus was soluble. Crystallin solubility analysis by SDS-PAGE and immunoblots revealed that relative proportions of crystallins in both soluble and urea-soluble fractions were similar within each species examined and in agreement with previous reports for bovine lens. From our data, we found that both toothfish and cow crystallins follow patterns of insolubility that mirror each animals lens composition with more γ crystallin aggregation seen in the toothfish lens nucleus than in cow. Toothfish lens lipids had a large amount of polyunsaturated fatty acids that were absent in cow resulting in an unsaturation index (I _U) four-fold higher than that of cow. We identified a novel FA with a molecular mass of 267 mass units in the lens epithelial layer of the toothfish that accounted for well over 50% of the FA abundance. The unidentified lipid in the toothfish lens epithelia corresponds to either an odd-chain (17 carbons) FA or a furanoid. We conclude that long-lived fishes are likely good animal models of lens crystallin solubility and may model post-translational modifications and solubility changes better than short-lived animal models.     

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.     

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.     

Comparative study of lens proteins of gray squirrel and human

1. The four crystallins of the gray squirrel lens have been characterized using gel filtration chromatography, polyacrylamide gel electrophoresis, and immunoblotting. Alpha, beta-heavy, beta-light, and gamma crystallins of squirrel lenses have been identified immunologically, and they cross-react strongly with rabbit polyclonal antibodies. The gamma-24 crystallin of the squirrel lens also reacts strongly with monoclonal anti-human lens gamma-24, as shown by its inhibition of the ELISA reaction by 85%. 2. The water-insoluble urea soluble proteins represent non-covalently associated species of soluble crystallins and the lens cytoskeletal proteins. The membrane intrinsic protein in the urea insoluble pellet has a mol. wt of 27,000 but other lower and higher mol. wt components are also present, which were removed by washing with 0.1 NaOH. The N-terminal 30 amino acid of squirrel lens gamma crystallin was found to be identical to that of the bovine (and human) lens. 3. Measurements of the distribution and state of SH and SS compounds in the squirrel lens have shown greater similarities to those of primates than those of rodents. The findings show that on the basis of both protein and sulfur chemistry the squirrel lens is a representative model for studies of oxidative lens changes in diurnal animals, including man.     

Effect of chronic hyperglycemia on crystallin levels in rat lens

Crystallins are the major structural proteins in the vertebrate eye lens that contribute to lens transparency. Although cataract, including diabetic cataract, is thought to be a result of the accumulation of crystallins with various modifications, the effect of hyperglycemia on status of crystallin levels has not been investigated. This study evaluated the effect of chronic hyperglycemia on crystallin levels in diabetic cataractous rat lens. Diabetes was induced in rats by injecting streptozotocin and maintained on hyperglycemia for a period of 10 weeks. At the end, levels of α-, β-, γ-crystallins and phosphoforms of αB-crystallins (αBC) were analyzed by immunoblotting. Further, solubility of crystallins and phosphoforms of αBC was analyzed by detergent soluble assay. Chronic diabetes significantly decreased the protein levels of α-, β- and αA-crystallins (αAC) in both soluble and insoluble fraction of lens. Whereas γ-crystallin levels were decreased and αBC levels were increased in lens soluble fraction with no change in insoluble fraction in diabetic rat lens. Although, diabetes activated the p38MAPK signaling cascade by increasing the p-p38MAPK in lens, the phosphoforms of αBC were decreased in soluble fraction with a concomitant increase in insoluble fraction of diabetic lens when compared to the controls. Moreover, diabetes strongly enhances the degradation of crystallins and phosphoforms of αBC in lens. Taken together, the decreased levels of crystallins and insolubilization of phosphoforms of αBC under chronic hyperglycemia could be one of the underlying factors in the development of diabetic cataract.     

A novel crystallin from octopus lens

Lens crystallins were isolated from cephalopods, octopus and squid. Two protein fractions were obtained from the octopus in contrast to only one crystallin from the squid. The native molecular mass for these purified fractions and their polypeptide compositions were determined by gel filtration, sedimentation analysis, and SDS-gel electrophoresis. Octopod and decapod lenses share one common major squid-type crystallin of 29 kDa, with one additional novel crystallin present only in the octopus lens. This newly-characterized crystallin (termed omega-crystallin) exists as a tetrameric protein of 230 kDa, consisting of 4 identical subunits of approx. 59 kDa. It is distinct from the previously known crystallins both in amino acid composition and subunit structure. N-terminal sequence analysis indicated that the omega-crystallin is N-terminally blocked, whereas the major octopus crystallin is identical to the reported squid crystallin with regard to the first 25 residues of protein sequence. Sequence similarity between this major cephalopod crystallin and glutathione S-transferase were found, which suggested some enzymatic role of crystallins inside the cephalopod lens.     

用蛋白质印迹转移技术分析正常及硒性白内障大鼠晶状体及房水中蛋白质的性质

本文用蛋白质印迹转移技术分析了正常及硒性白内障大鼠晶状体及房水中蛋白质的性质。结果表明,晶状体中的脲溶性蛋白质可被抗α及抗γ晶体蛋白血清识别,提示α及γ晶体蛋白均为脲溶性蛋白质的主要成份。患白内障时房水中的蛋白质含量明显增加,且主要被抗γ血清识别,而被抗α血清识别的成份很少,表明在大鼠硒性白内障形成过程中,有较多低分子量蛋白质漏出到房水中,且其主要成份为γ晶体蛋白。此外,我们还发现正常及硒性白内障大鼠晶状体膜蛋白质与抗α及抗γ血清起反应的程度及分布有所不同,提示晶状体细胞膜与晶体蛋白之间存在着相互作用。