X-ray diffraction in the intact isolated frog ocular lens

X-ray diffraction method has been applied for investigating ocular lens native tissue of the frog. X-ray diffraction patterns of intact lenses, their nuclei and cortices are similar and contain a set of concentric diffuse diffraction maxima. The most intensive of these maxima corresponding to the Bragg-spacings of 14.6, 9.1 and 4.6 A are presumably associated with intramolecular structure of lens proteins--crystallins. Intensive small-angle X-ray scattering and diffraction patterns isotropy indicates unavailability of crystallin molecule ordering or orientation in the lens. The shift of 14.6 A maximum up to 12.8 A being the result of nuclei drying shows the necessity of aqueous surrounding for these protein native structure maintenance.     

Comparative study of bovine ocular lens proteins in native tissue and an extract using the x-ray diffraction method

It has been shown that the maxima (Bragg-spacings 4,5-19 A) on the X-ray diffraction patterns of the bovine lens native tissues from nuclear and cortical parts are predominantly due to the water-soluble crystallin intramolecular structure. The structures of water-soluble and water-insoluble fractions from bovine lens nucleus and cortex were qualitatively compared. Reversible dependence of the lens water-soluble protein structure on water content in the system was demonstrated.     

Heat-induced structural transition of α-crystallin in the eye lens tissue observed by small-angle X-ray scattering

Heat-induced structural transitions of crystallins in the eye lens tissue have been studied by small-angle X-ray scattering. It is shown that a short-time (～1 min) incubation of the bovine lens tissue at a temperature of ～60°C leads to a pronounced shift of the small-angle x-ray diffraction maximum due to the short-range order of α-crystallin oligomers. This shift indicates an increase in the molecular mass of α-crystallin oligomers. The results are evidence that, in the native surrounding and at the natural concentration of α-crystallin, heat-induced transition of α-crystallin quaternary structure takes place. Earlier, this transition of α-crystallin has been observed only in solutions and gels of this protein. The results confirm the identity of α-crystallin properties in vitro and in vivo.     

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.     

Comparative x-ray diffraction study of the crystalline lens in a number of vertebrates including man

X-ray diffraction method has been applied for comparative investigation of native structure of eye lens proteins (crystallins). X-ray diffraction patterns of the whole lenses and/or their nuclear parts were obtained for man and vertebrate animals. Crystalline lenses of the fishes Acerina cernua and Pelmatochromis kribensis, frog Rana temporaria, bull and man contain crystallins with a very similar secondary and tertiary structure, whereas lenses of chicks and the tortoise Testudo horsfieldi contain mainly crystallins with other structure. The results obtained reveal evolutionary conservatism of crystallin structure in fishes, amphibians and mammals. It was also concluded that there is no correlation between crystallin structure of the lens, elasticity of the latter and accommodation mechanism.     

Molecular basis of eye lens transparency. Osmotic pressure and X-ray analysis of alpha-crystallin solutions

Short range, liquid-like order of the crystallin proteins accounts for eye lens transparency. The relationship between structural and thermodynamic properties of eye lens was further investigated using osmotic pressure and small-angle X-ray scattering measurements of calf lens alpha-crystallins. The consistency of both data sets confirms that the macroscopic thermodynamic properties are determined by the structural properties accessible to X-ray scattering. In addition, the experimental data were correctly accounted for using a model developed in liquid-state physics: the rescaled mean spherical approximation combined with a Verwey-Overbeek potential. This model provides as best fit parameters the excluded volume, the charge and the diameter of an "equivalent" particle that compare well with the corresponding values found in the literature for alpha-crystallins. As a result, transparency may now be expressed as a function of a few structural parameters, the role of which is discussed. The approach presented here may be extended to studies of the thermodynamic-structural relationships of other protein solutions.     

The Structure and Stability of the Disulfide-Linked γS-Crystallin Dimer Provide Insight into Oxidation Products Associated with Lens Cataract Formation

The reducing environment in the eye lens diminishes with age, leading to significant oxidative stress. Oxidation of lens crystallin proteins is the major contributor to their destabilization and deleterious aggregation that scatters visible light, obscures vision, and ultimately leads to cataract. However, the molecular basis for oxidation-induced aggregation is unknown. Using X-ray crystallography and small-angle X-ray scattering, we describe the structure of a disulfide-linked dimer of human γS-crystallin that was obtained via oxidation of C24. The γS-crystallin dimer is stable at glutathione concentrations comparable to those in aged and cataractous lenses. Moreover, dimerization of γS-crystallin significantly increases the protein’s propensity to form large insoluble aggregates owing to non-cooperative domain unfolding, as is observed in crystallin variants associated with early-onset cataract. These findings provide insight into how oxidative modification of crystallins contributes to cataract and imply that early-onset and age-related forms of the disease share comparable development pathways.     

Structural changes in alpha-crystallin and whole eye lens during heating, observed by low-angle X-ray diffraction

Whole eye lens and alpha-crystallin gels and solutions were investigated using X-ray scattering techniques at temperatures ranging from 20 degrees C to 70 degrees C. In whole lens isolated in phosphate-buffered saline, the spacing of the dominant X-ray reflection seen with low-angle scattering was constant from 20 degrees C to 45 degrees C but increased at 50 degrees C from 15.2 nm to 16.5 nm. At room temperature, the small-angle X-ray diffraction pattern of the intact lens was very similar to the pattern of alpha-crystallin gels at near-physiological concentration (approximately 300 mg/ml), so it is reasonable to assume that the alpha-crystallin pattern dominates the pattern of the intact lens. Our results therefore indicate that in whole lens alpha-crystallin is capable of maintaining its structural properties over a wide range of temperature. This property would be useful in providing protection for other lens proteins super-aggregating. In the alpha-crystallin gels, a moderate increase in both the spacing and intensity of the reflection was observed from 20 degrees C to 45 degrees C, followed by an accelerated increase from 45 degrees C to 70 degrees C. Upon cooling, this effect was found to be irreversible over 11 hours. Qualitatively similar results were observed for alpha-crystallin solutions at a variety of lower concentrations.     

Isolation and cell-free translation of chick lens crystallin mRNA during normal development and transdifferentiation of neural retina

Messenger RNA has been isolated from day-old chick lens. Size characterization and heterologous cell-free translation demonstrate that the predominant species of mRNA present code for α-, β- and δ-crystallins. Total polysomal RNA and polysomal RNA which did not bind to oligo (dT)-cellulose translate in the cell-free system to give a crystallin profile qualitatively similar to that of poly(A)⁺ mRNA. RNA from postribosomal supernatant which binds to oligo(dT)-cellulose also translates to give crystallins, but the products are enriched for β-crystallins. Messenger RNAs isolated from 15-day embryo lens fiber and lens epithelium cells give products on translation which reflect the different protein compositions of these two cell types, as do mRNAs isolated from chick lenses at various developmental stages. Messenger RNAs were isolated from freshly excised 8-day embryo neural retina and from this tissue undergoing transdifferentiation into lens cells in cell culture. Cell-free translation demonstrates no detectable crystallin mRNAs in the freshly excised material, but by 42 days in cell culture, crystallin mRNAs are the most prominent species.     

Convergent evolution of crystallin gene regulation in squid and chicken: The AP-1/ARE connection

Previous experiments have shown that the minimal promoters required for function of the squid SL20-1 and SL11 crystallin genes in transfected rabbit lens epithelial cells contain an overlapping AP-1/antioxidant responsive element (ARE) upstream of the TATA box. This region resembles the PL-1 and PL-2 elements of the chicken B 1-cry stallin promoter which are essential for promoter function in transfected primary chicken lens epithelial cells. Here we demonstrate by site-directed mutagenesis that the AP-1/ARE sequence is essential for activity of the squid SL20-1 and SL11 promoters in transfected embryonic chicken lens cells and fibroblasts. Promoter activity was higher in transfected lens cells than in fibroblasts. Electrophoretic mobility shift and DNase protection experiments demonstrated the formation of numerous complexes between nuclear proteins of the embryonic chicken lens and the AP-1/ARE sequences of the squid SL20-1 and SL11 crystallin promoters. One of these complexes comigrated and cross-competed with that formed with the PL-1 element of the chicken B1-crystallin promoter. This complex formed with nuclear extracts from the lens, heart, brain, and skeletal muscle of embryonic chickens and was eliminated by competition with a consensus AP-1 sequence. The nonfunctional mutant AP-1/ ARE sequences did not compete for complex formation. These data raise the intriguing possibility that entirely different, nonhomologous crystallin genes of the chicken and squid have convergently evolved a similar cis-acting regulatory element (AP-1/ARE) for high expression in the lens. Correspondence to: S. I. Tomarev     

Biochemical characterization of crystallins from pigeon lenses: structural and sequence analysis of pigeon delta-crystallin.

Crystallins from pigeon eye lenses were isolated and purified by gel-permeation chromatography and characterized by gel electrophoresis, amino-acid composition and sequence analysis. Alpha- and beta-crystallins could be obtained in relatively pure forms by single-step size-exclusion chromatography whereas an extra step of ion-exchange chromatography was needed for the separation of delta-crystallin from the beta-crystallin fraction. In contrast to most characterized vertebrate species, a large amount of glycogen is eluted as a high molecular form in the first peak of the gel filtration column. Pigeon delta-crystallin, similar to duck and reptilian delta-crystallins, exists as a tetrameric structure of about 200 kDa in the native form and is composed of one major subunit of 50 kDa with heterogeneous isoelectric points spreading in a range of 4.7 to 6.8. In contrast to those obtained from duck, goose and caiman, delta-crystallin isolated from the pigeon lens possessed very little argininosuccinate lyase activity. However, pigeon delta-crystallin can still cross-react with the antibody against enzymically active duck delta-crystallin as revealed by the sensitive immunoblotting technique. It was also shown that the delta-crystallin content of the total pigeon soluble proteins decreased with the age of the animal. Structural analysis of purified delta-crystallin fraction was made with respect to its amino-acid composition and protein primary sequence. N-terminal sequence analysis indicated the presence of blocked amino-termini in all crystallin fractions of pigeon lenses. Therefore, a sequence analysis of PCR (polymerase chain reaction) amplified delta-crystallin cDNA was employed to deduce the protein sequence of this crystallin. Structural comparison of delta-crystallin sequences from pigeon, chicken and duck lenses casts some doubts on the recent claim that His-89-->Gln mutation in the chicken delta-crystallin may account for the loss of argininosuccinate lyase activity in this avian species, as compared to high enzymic activity in the duck crystallin (Barbosa et al. (1991) J. Biol. Chem. 266, 5286-5290).     

The appearance of α, β and γ crystallins in an anophthalmic strain of mice

Abstract. A certain percentage of congenitally anophthalmic mouse embryos have the ability to generate small lens vesicles that have previously been shown to produce alpha crystallin at 13-day gestation. Further immunohistological analysis of 13- and 15-day-gestation anophthalmia embryos indicates that beta crystallin is present in those 13-day embryos which have lens vesicles with lens-fiber formation. Also, 15-day embryos with lenses demonstrating fiber elongation can produce both beta and gamma crystallins. The conclusion is drawn that the genetic potential to produce at least three characteristic biochemical markers of normal lens differentiation is present in the anophthalmia mutant. The spatial distribution patterns of the crystallins in normal and anophthalmia embryos were similar. However, there appeared to be a transposition in the temporal appearance of beta and gamma crystallins in the anophthalmia mutant. Optic cups and associated lenses in 15-day anophthalmia specimens were much smaller than those in controls. The optic and lens rudiments in these anophthalmia embryos were fairly proportional in size, which indicates that some degree of allometric growth compensation had occurred during the course of development. This ability for differential growth compensation in the mouse eye appears to be restricted to the predifferentiative stages of eye formation.     

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 proteasome shows enhanced rates of degradation of hydroxyl radical modified alpha-crystallin

Proteasome, a high molecular weight protease complex (HMP, approximately 600 kDa) was isolated from bovine eye lens epithelium tissue. In contrast with prior reports, lens proteasome degraded the major lens protein alpha-crystallin and S-carboxymethylated bovine serum albumin at 37 degrees C, mostly to trichloroacetic acid precipitable polypeptides. The proteasome, thus isolated, was labile at 55 degrees C. As indicated by the ability of p-chloromercuribenzoate and N-ethylmaleimide to block activity, a thiol group is required for activity. Alpha-crystallin was oxidized by exposure to 60Co-irradiation under an atmosphere of N2O (1-50 kilorads). This dose delivered 0.1-5.7 mol of hydroxyl radicals per mol of crystallin. Irradiation resulted in increased heterogeneity, aggregation, and fragmentation of the crystallin preparation. The proteolytic susceptibility of alpha-crystallin to the lens HMP was enhanced by the irradiation in a dose-dependent manner up to 20 kilorads (.OH concentration up to 2.3 mol per mol of alpha-crystallin). When 50 kilorads (5.7 mol .OH per mol of alpha-crystallin) was used, there was extensive aggregation and no enhancement in proteolysis over the unirradiated sample. The data indicate that the lens HMP can degrade mildly photooxidized lens proteins, but proteins which are extensively damaged are not degraded and may accumulate. This may be related to cataract formation.     

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.     

Electrophoretic variation in low molecular weight lens crystallins from inbred strains of rats

Analysis of rat lens soluble proteins by analytical isoelectric focusing detected two inherited electrophoretic differences in low molecular weight (LM) crystallins from inbred strains of rats (Rattus norvegicus). The polymorphic lens crystallins were shown to be similar to a genetically variant LM crystallin, LEN-1, previously described in mice (Mus musculus) and encoded on chromosome 1, at a locus linked to Pep-3 (dipeptidase). Linkage analysis demonstrated that the rat crystallin locus was loosely linked to Pep-3 at a recombination distance of 38 +/- 4.5 U. These data suggest the conservation of a large chromosomal region during the evolution of Rodentia and support the hypothesis that the gamma-crystallins are evolving more rapidly than alpha- or beta-crystallins.     

Association properties of betaB1- and betaA3-crystallins: ability to form heterotetramers

As major constituents of the mammalian lens, beta-crystallins associate into dimers, tetramers, and higher-order complexes to maintain lens transparency and refractivity. A previous study has shown that dimerization of betaB2- and betaA3-crystallins is energetically highly favored and entropically driven. While heterodimers further associate into higher-order complexes in vivo, a significant level of reversibly associated tetrameric crystallin has not been previously observed in vitro. To enhance our understanding of the interactions between beta-crystallins, we characterized the association of betaB1-crystallin, a major component of large beta-crystallin complexes (beta-high), with itself and with betaA3-crystallin. Mouse betaB1-crystallin and human betaA3-crystallin were expressed in Escherichia coli and purified chromatographically. Their association was then characterized using size-exclusion chromatography, native gel electrophoresis, isoelectric focusing, and analytical sedimentation equilibrium centrifugation. When present alone, each beta-crystallin associates into homodimers; however, no tetramer formation is seen. Once mixing has taken place, formation of a heterocomplex between betaB1- and betaA3-crystallins is observed using size-exclusion chromatography, native gel electrophoresis, isoelectric focusing, and sedimentation equilibrium. In contrast to results previously obtained after betaB2- and betaA3-crystallins had been mixed, mixed betaB1- and betaA3-crystallins show a dimer-tetramer equilibrium with a K d of 1.1 muM, indicating that these two beta-crystallins associate predominantly into heterotetramers in vitro. Thus, while each purified beta-crystallin associates only into homodimers and under the conditions studied mixed betaB2- and betaA3-crystallins form a mixture of homo- and heterodimers, mixed betaB1- and betaA3-crystallins associate predominantly into heterotetramers in equilibrium with heterodimers. These findings suggest a unique role for betaB1-crystallin in promoting higher-order crystallin association in the lens.