Distinct roles of alphaA- and alphaB-crystallins under thermal and UV stresses

alpha-Crystallin, a major protein of all vertebrate lenses, consists of two subunits, alphaA and alphaB, which form polymeric aggregates with an average molecular mass of about 800kDa. In this study, we have employed various biophysical methods to study aggregate sizes and conformational properties of purified alphaA, alphaB subunits, and cloned recombinant alphaB subunit. From far- and near-UV CD spectra, native alpha-, alphaA-, alphaB-, and recombinant alphaB-crystallins from porcine lenses all show similar beta-sheet conformation to that from bovine and human lenses as reported previously. By means of gel-filtration chromatography and dynamic light scattering, we have found that the molecular sizes of all four crystallin aggregates are polydispersedly distributed in the following order of aggregate sizes, i.e., native alpha>alphaA>alphaB approximately recombinant alphaB. To investigate the structural and functional relationships, we have also compared the chaperone activities of all four alpha-crystallin aggregates at different temperatures. From the results of chaperone-activity assays, ANS (8-anilinonaphthalene-1-sulfonic acid) binding and thermal stability studies, there appeared to be at least two factors playing major roles in the chaperone-like activity of these lens proteins: one is the hydrophobicity of the exposed protein surface and the other is the structural stability associated with each protein. We showed that alphaA-crystallin is a better chaperone to protect gamma-crystallin against UV irradiation than alphaB-crystallin, in contrast to the observation that alphaB is generally a better chaperoning protein than alphaA for enzyme protective assays at physiological temperatures.     

Mechanism of small heat shock protein function in vivo: a knock-in mouse model demonstrates that the R49C mutation in alpha A-crystallin enhances protein insolubility and cell death

alphaA-crystallin (Cryaa/HSPB4) is a small heat shock protein and molecular chaperone that prevents nonspecific aggregation of denaturing proteins. Several point mutations in the alphaA-crystallin gene cause congenital human cataracts by unknown mechanisms. We took a novel approach to investigate the molecular mechanism of cataract formation in vivo by creating gene knock-in mice expressing the arginine 49 to cysteine mutation (R49C) in alphaA-crystallin (alphaA-R49C). This mutation has been linked with autosomal dominant hereditary cataracts in a four-generation Caucasian family. Homologous recombination in embryonic stem cells was performed using a plasmid containing the C to T transition in exon 1 of the cryaa gene. alphaA-R49C heterozygosity led to early cataracts characterized by nuclear opacities. Unexpectedly, alphaA-R49C homozygosity led to small eye phenotype and severe cataracts at birth. Wild type littermates did not show these abnormalities. Lens fiber cells of alphaA-R49C homozygous mice displayed an increase in cell death by apoptosis mediated by a 5-fold decrease in phosphorylated Bad, an anti-apoptotic protein, but an increase in Bcl-2 expression. However, proliferation measured by in vivo bromodeoxyuridine labeling did not decline. The alphaA-R49C heterozygous and homozygous knock-in lenses demonstrated an increase in insoluble alphaA-crystallin and alphaB-crystallin and a surprising increase in expression of cytoplasmic gamma-crystallin, whereas no changes in beta-crystallin were observed. Co-immunoprecipitation analysis showed increased interaction between alphaA-crystallin and lens substrate proteins in the heterozygous knock-in lenses. To our knowledge this is the first knock-in mouse model for a crystallin mutation causing hereditary human cataract and establishes that alphaA-R49C promotes protein insolubility and cell death in vivo.     

AlphaA-crystallin interacting regions in the small heat shock protein, alphaB-crystallin

Amino acid sequences of alphaB-crystallin, involved in interaction with alphaA-crystallin, were determined by using peptide scans. Positionally addressable 20-mer overlapping peptides, representing the entire sequence of alphaB-crystallin, were synthesized on a PVDF membrane. The membrane was blocked with albumin and incubated with purified alphaA-crystallin. Probing the membrane with alphaA-crystallin-specific antibodies revealed residues 42-57, 60-71, and 88-123 in alphaB-crystallin to interact with alphaA-crystallin. Residues 42-57 and 60-71 interacted more strongly with alphaA-crystallin than the 88-123 sequence of alphaB-crystallin. Binding of one of the alphaB peptides (42-57) to alphaA-crystallin was also confirmed by gel filtration studies and HPLC analysis. The alphaB-crystallin sequences involved in interaction with alphaA-crystallin were distinct from the chaperone sites reported earlier as binding of the alphaB sequence from residues 42-57 does not alter the chaperone-like function of alphaA-crystallin. To identify the critical residues involved in interaction with alphaA-crystallin, R50G and P51A mutants of alphaB-crystallin were made and tested for their ability to interact with alphaA-crystallin. The oligomeric size and hydrophobicity of the mutants were similar. Circular dichroism studies showed that the P51A mutation increased the alpha-helical content of the protein. While the alphaBR50G mutant showed chaperone-like activity similar to wild-type alphaB, alphaBP51A showed reduced chaperone function. Fluorescence resonance energy transfer studies showed that the P51A mutation decreased the rate of subunit exchange with alphaA by 63%, whereas the R50G mutation reduced the exchange rate by 23%. Similar to wild-type alphaB, alphaB-crystallin peptide (42-57) effectively competed with alphaBP51A and alphaBR50G for interaction with alphaA. Thus, our studies showed that the alphaB-crystallin sequence (42-57) is one of the interacting regions in alphaB and alphaA oligomer formation.     

Thermodynamic stability of human lens recombinant alphaA- and alphaB-crystallins

Lens alpha-crystallin is a 600-800-kDa heterogeneous oligomer protein consisting of two subunits, alphaA and alphaB. The homogeneous oligomers (alphaA- and alphaB-crystallins) have been prepared by recombinant DNA technology and shown to differ in the following biophysical/biochemical properties: hydrophobicity, chaperone-like activity, subunit exchange rate, and thermal stability. In this study, we studied their thermodynamic stability by unfolding in guanidine hydrochloride. The unfolding was probed by three spectroscopic parameters: absorbance at 235 nm, Trp fluorescence intensity at 320 nm, and far-UV circular dichroism at 223 nm. Global analysis indicated that a three-state model better describes the unfolding behavior than a two-state model, an indication that there are stable intermediates for both alphaA- and alphaB-crystallins. In terms of standard free energy (DeltaG(NU)(H(2)(O))), alphaA-crystallin is slightly more stable than alphaB-crystallin. The significance of the intermediates may be related to the functioning of alpha-crystallins as chaperone-like molecules.     

Enhancer-independent promoter activity of the mouse alphaB-crystallin/small heat shock protein gene in the lens and cornea of transgenic mice

The alphaB-crystallin/small heat shock protein gene is expressed very highly in the mouse eye lens and to a lesser extent in many other nonocular tissues, including the heart, skeletal muscle and brain. Previously we showed in transgenic mice that lens-specific alphaB-crystallin promoter activity is directed by a proximal promoter fragment (-164/+44) and that non-lens promoter activity depends on an upstream enhancer (-427/-259) composed of at least 5 cis-control elements. Here we have used truncated alphaB-crystallin promoter-CAT transgenes to test by biphasic CAT assays and/or histochemistry for specific expression in the cornea and lens. Deletion either of 87 bp (-427/-340) from the 5' end of the alphaB-crystallin enhancer or of the whole enhancer (-427/-258) abolished alphaB-crystallin promoter activity in all tissues except the lens and corneal epithelium when examined by the biphasic CAT assay in 4-5-week-old transgenic mice. These truncations also lowered promoter strength in the lens. The -426/+44-CAT, -339/+44-CAT and -164/+44-CAT (previously thought to be lens-specific in transgenic mice) transgenes were all expressed in the 4-6-week-old corneal epithelium when examined histochemically. Immunohistochemical staining confirmed the presence of endogenous alphaB-crystallin in the mature corneal epithelial cells. CAT gene expression driven by the alphaB-crystallin promoter with or without the enhancer was evident in the embryonic and 4-6-week-old lens. By contrast, activity of the alphaB-crystallin promoter/enhancer-CAT transgene was not detectable in the corneal epithelium before birth. Taken together, these results indicate that the intact enhancer of the alphaB-crystallin/small heat shock protein gene is required for promoter activity in all tissues tested except the lens and cornea.     

Increased content of zinc and iron in human cataractous lenses

The purpose of the study was to examine the zinc and iron content of human lenses in different types of cataract and to investigate the possible influence of diabetes on the zinc and iron content of the lens. Iron and zinc of 57 human lenses (28 corticonuclear cataracts and 29 mature cataracts with a mean age of 70.6±16.1 and 74.7±11.1 yr, 41 nondiabetics and 16 diabetics) were determined by atomic absorption spectroscopy. The zinc content of human lenses was significantly increased in mature cataracts compared to corticonuclear cataracts (0.51±0.33 vs 0.32±0.20 μmol/g dry mass, p=0.012). The iron content of mature cataracts was also higher than in corticonuclear cataracts (0.11±0.09 vs 0.07±0.05 μmol/g dry mass, p=0.071). Furthermore, a significant increase of the lens zinc content could be observed with increasing lens coloration (light brown 0.33±0.17 vs dark brown 0.52±0.35 μmol/g dry mass, p=0.032). Diabetic patients seem to have both increased zinc and iron contents in the lens compared to nondiabetic subjects (zinc: 0.45±0.42 vs 0.40±0.22 μmol/g dry mass; iron: 0.12±0.10 vs 0.08±0.05 μmol/g dry mass). These data suggest a possible influence of the lens zinc and iron content on the development of lens opacification. Especially advanced forms of cataract and dark brown colored lenses show significantly increased zinc and iron content.     

Enhanced expression of the human CD14 protein in tobacco using a 22-kDa alpha-zein signal peptide

The human CD14, a high affinity receptor for lipopolysaccharides (LPS), is involved in the innate immunity system and the inflammatory response. There is increasing interest in using recombinant approaches to produce purified CD14 protein for therapeutic uses. Plants provide ideal expression systems for the production of recombinant proteins, but the levels of expression of recombinant proteins produced in planta are still not high. To improve expression levels of CD14 the 22-kDa alpha-zein signal peptide (ZSP) from maize was fused to the human CD14 cDNA so that recombinant CD14 could stably accumulate in plant cells. The human CD14 gene and the modified human CD14 cDNA with the 22-kDa ZSP were respectively transformed into tobacco to produce transgenic plants. Western blot analysis confirmed human CD14 accumulation in the transgenic tobacco. The concentration of the recombinant protein in the tobacco leaves was measured by ELISA, and the results suggested that fusion with the 22-kDa alpha-ZSP effectively increased the accumulation of the recombinant protein (rCD14). The concentration of rCD14 in some of the transgenic lines was 19.54???g?g^?1 tobacco leaf (fw), which was about 0.6?% of the total soluble protein. The rCD14 protein showed natural LPS-binding bioactivity by using U937 cells mensuration. Our results suggested that the maize 22-kDa alpha-zein signal peptide could be used to increase the accumulation of recombinant protein in tobacco leaves so that proteins can be produced in abundant biomass.     

Recognition sequence 2 (residues 60-71) plays a role in oligomerization and exchange dynamics of alphaB-crystallin

Previously, using the peptide scan method, we have determined that residues 42-57 and 60-71 in alphaB-crystallin (TSLSPFYLRPPSFLRA, named recognition sequence 1 or RS-1, and WFDTGLSEMRLE, named recognition sequence 2 or RS-2) are involved in interaction with alphaA-crystallin. To understand the significance of the RS-2 region in interactions between alphaA- and alphaB-crystallins, W60R, F61N, and S66G mutants of alphaB-crystallin were made and tested for their ability to interact with alphaA-crystallin. W60R and S66G mutations increased the oligomeric size of alphaB-crystallin by 1.6- and 2.7-fold respectively, whereas the F61N mutation had no effect. The tryptophan fluorescence intensity of alphaBS66G was 1.5-fold higher than that for the wild type. The intrinsic fluorescence of alphaBF61N was marginally lower than that of alphaB, whereas the fluorescence intensity of alphaBW60R decreased by 40% compared with that of alphaB. The relative availability of hydrophobic sites in the mutants was in the following order: alphaBS66G > alphaB = alphaBF61N = alphaBW60R. The far-UV CD profiles for the wild type and alphaB-crystallin mutants indicated no significant changes in their secondary structures, except for alphaBS66G, which showed an increase in alpha-helical content. The near-UV CD profiles of alphaBW60R and alphaBF61N were nearly similar to that of wild type alphaB. On the other hand, alphaBS66G beyond 270 nm exhibited a signature completely different from that of wild type alphaB. Mutations did not alter the chaperone-like activity of these proteins. The W60R mutation did not affect the rate of subunit exchange between alphaB- and alphaA-crystallins. On the other hand, the S66G mutation increased the subunit exchange rate by 100%, whereas the F61N mutation decreased the rate of subunit exchange between alphaB- and alphaA-crystallins by 36%. Our results establish the importance of residues 60-71 in oligomerization of alphaB-crystallin and subunit interaction between alphaB- and alphaA-crystallins.     

Temperature-dependent chaperone activity and structural properties of human alphaA- and alphaB-crystallins

The chaperone activity and biophysical properties of recombinant human alphaA- and alphaB-crystallins were studied by light scattering and spectroscopic methods. While the chaperone function of alphaA-crystallin markedly improves with an increase in temperature, the activity of alphaB homopolymer appears to change very little upon heating. Compared with alphaB-crystallin, the alphaA-homopolymer is markedly less active at low temperatures, but becomes a more active species at high temperatures. At physiologically relevant temperatures, the alphaB homopolymer appears to be modestly (two times or less) more potent chaperone than alphaA homopolymer. In contrast to very similar thermotropic changes in the secondary structure of both homopolymers, alphaA- and alphaB-crystallins markedly differ with respect to the temperature-dependent surface hydrophobicity profiles. Upon heating, alphaA-crystallin undergoes a conformational transition resulting in the exposure of additional hydrophobic sites, whereas no such transition occurs for alphaB-crystallin. The correlation between temperature-dependent changes in the chaperone activity and hydrophobicity properties of the individual homopolymers supports the view that the chaperone activity of alpha-crystallin is dependent on the presence of surface-exposed hydrophobic patches. However, the present data also show that the surface hydrophobicity is not the sole determinant of the chaperone function of alpha-crystallin.     

Elevated expression of alphaA- and alphaB-crystallins in streptozotocin-induced diabetic rat

alpha-Crystallin, a predominant protein of the ocular lens, is composed of two subunits, alphaA and alphaB. Of these, alphaB-crystallin has been shown to present widely in non-lenticular tissues while alphaA-crystallin is largely lens-specific. Although, expression of alphaB-crystallin is elevated under various stress and pathological conditions, yet its physiological significance remained unknown. Some studies suggest that the expression of alphaB-crystallin gene is related to oxidative stress. Persistent hyperglycemia during uncontrolled diabetes is known to cause oxidative stress, which has been implicated in various secondary complications of diabetes. Hence, expression of alphaA- and alphaB-crystallins in various tissues of streptozotocin (STZ)-induced diabetic Wistar-NIN rats was investigated by RT-PCR and immunoblotting. While expression of alphaB-crystallin was noted in the wide range of tissues examined in the study, alphaA-crystallin expression was detected only in lens and retina. Interestingly, alphaB-crystallin expression was elevated in lens, heart, muscle, and brain, but decreased in adipose tissue of diabetic rats compared to control rats. alphaA-Crystallin expression was increased in retina of diabetic rat. Increased oxidative stress appears to be a major stimulus for the enhanced expression of alphaA- and alphaB-crystallins in the tissues of diabetic rats and elevated expression of alpha-crystallin may have a protective role against metabolic stress. Interestingly, feeding of curcumin, a dietary antioxidant, to diabetic rats attenuated the enhanced expression of alphaB-crystallin. The results indicate that elevated expression of alpha-crystallins in some tissues may have implications in pathophysiology of diabetic complications.     

Determination of calcium, sodium, potassium and magnesium concentrations in human senile cataractous lenses

Cataractous lenses have been found to have a distribution of the intracellular ionic environment, the concentrations of potassium and magnesium decreasing and the concentrations of sodium and calcium increasing relative to the cytosol of most cells. This arises as a result of changes to lens membrane characteristics causing an increase in lens membrane permeability. These changes have been found to be initiated as a result of normal ageing of the human lens. In this study, total Ca2+, K+, Na+ and Mg2+ contents have been determined in human normal and cataractous lenses using atomic absorption and flame emission spectroscopy. The normal human lens Ca2+ is between 0.15 and 0.5 miromol g(-1) fresh lens weight; in senile cataracts the value increased up to 9.31 micromol g(-1) ( p < 0.0001). The normal levels of Na+, Mg2+ and K+ are 20, 5.5 and 60 micromol g(-1) respectively; these changed to 136.10, 3.60 and 9.33 micro mol g(-1), respectively in cataractous senile human lenses ( p < 0.002, p < 0.002 and p < 0.01). The remarkable differences in these elements may play some role in cataractogenesis.     

A novel quaternary structure of the dimeric alpha-crystallin domain with chaperone-like activity

alphaB-crystallin, a member of the small heat-shock protein family and a major eye lens protein, is a high molecular mass assembly and can act as a molecular chaperone. We report a synchrotron radiation x-ray solution scattering study of a truncation mutant from the human alphaB-crystallin (alphaB57-157), a dimeric protein that comprises the alpha-crystallin domain of the alphaB-crystallin and retains a significant chaperone-like activity. According to the sequence analysis (more than 23% identity), the monomeric fold of the alpha-crystallin domain should be close to that of the small heat-shock protein from Methanococcus jannaschii (MjHSP16.5). The theoretical scattering pattern computed from the crystallographic model of the dimeric MjHSP16.5 deviates significantly from the experimental scattering by the alpha-crystallin domain, pointing to different quaternary structures of the two proteins. A rigid body modeling against the solution scattering data yields a model of the alpha-crystallin domain revealing a new dimerization interface. The latter consists of a strand-turn-strand motif contributed by each of the monomers, which form a four-stranded, antiparallel, intersubunit composite beta-sheet. This model agrees with the recent spin labeling results and suggests that the alphaB-crystallin is composed by flexible building units with an extended surface area. This flexibility may be important for biological activity and for the formation of alphaB-crystallin complexes of variable sizes and compositions.     

Lens Crystallin Modifications and Cataract in Transgenic Mice Overexpressing Acylpeptide Hydrolase

The accumulation of crystallin fragments in vivo and their subsequent interaction with crystallins are responsible, in part, for protein aggregation in cataracts. Transgenic mice overexpressing acylpeptide hydrolase (APH) specifically in the lens were prepared to test the role of protease in the generation and accumulation of peptides. Cataract development was seen at various postnatal days in the majority of mice expressing active APH (wt-APH). Cataract onset and severity of the cataracts correlated with the APH protein levels. Lens opacity occurred when APH protein levels were >2.6% of the total lens protein and the specific activity, assayed using Ac-Ala-p-nitroanilide substrate, was >1 unit. Transgenic mice carrying inactive APH (mt-APH) did not develop cataract. Cataract development also correlated with N-terminal cleavage of the APH to generate a 57-kDa protein, along with an increased accumulation of low molecular weight (LMW) peptides, similar to those found in aging human and cataract lenses. Nontransgenic mouse lens proteins incubated with purified wt-APH in vitro resulted in a >20% increase in LMW peptides. Crystallin modifications and cleavage were quite dramatic in transgenic mouse lenses with mature cataract. Affected lenses showed capsule rupture at the posterior pole, with expulsion of the lens nucleus and degenerating fiber cells. Our study suggests that the cleaved APH fragment might exert catalytic activity against crystallins, resulting in the accumulation of distinct LMW peptides that promote protein aggregation in lenses expressing wt-APH. The APH transgenic model we developed will enable in vivo testing of the roles of crystallin fragments in protein aggregation.     

Functional similarities between the small heat shock proteins Mycobacterium tuberculosis HSP 16.3 and human alphaB-crystallin.

Mycobacterium tuberculosis heat shock protein 16.3 (MTB HSP 16.3) accumulates as the dominant protein in the latent stationary phase of tuberculosis infection. MTB HSP 16.3 displays several characteristics of small heat shock proteins (sHsps): its expression is increased in response to stress, it protects against protein aggregation in vitro, and it contains the core 'alpha-crystallin' domain found in all sHsps. In this study we characterized the chaperone activity of recombinant MTB HSP 16.3 in several different assays and compared the results to those obtained with recombinant human alphaB-crystallin, a well characterized member of the sHsp family. Recombinant MTB HSP 16.3 was expressed in Escherichia coli and purified to apparent homogeneity. Similar to alphaB-crystallin, MTB HSP16.3 suppressed citrate synthase aggregation and in the presence of 3.5 mm ATP the chaperone activity was enhanced by twofold. ATP stabilized MTB HSP 16.3 against proteolysis by chymotrypsin, and no effect was observed with ATPgammaS, a nonhydrolyzable analog of ATP. Increased expression of MTB HSP 16.3 resulted in protection against thermal killing in E. coli at 48 degrees C. While the sequence similarity between human alphaB-crystallin and MTB HSP 16.3 is only 18%, these results suggest that the functional similarities between these proteins containing the core 'alpha-crystallin' domain are much closer.     

Structural and functional consequences of the mutation of a conserved arginine residue in alphaA and alphaB crystallins.

A point mutation of a highly conserved arginine residue in alphaA and alphaB crystallins was shown to cause autosomal dominant congenital cataract and desmin-related myopathy, respectively, in humans. To study the structural and functional consequences of this mutation, human alphaA and alphaB crystallin genes were cloned and the conserved arginine residue (Arg-116 in alphaA crystallin and Arg-120 in alphaB crystallin) mutated to Cys and Gly, respectively, by site-directed mutagenesis. The recombinant wild-type and mutant proteins were expressed in Escherichia coli and purified. The mutant and wild-type proteins were characterized by SDS-polyacrylamide gel electrophoresis, Western immunoblotting, gel permeation chromatography, fluorescence, and circular dichroism spectroscopy. Biophysical studies reveal significant differences between the wild-type and mutant proteins. The chaperone-like activity was studied by analyzing the ability of the recombinant proteins to prevent dithiothreitol-induced aggregation of insulin. The mutations R116C in alphaA crystallin and R120G in alphaB crystallin reduce the chaperone-like activity of these proteins significantly. Near UV circular dichroism and intrinsic fluorescence spectra indicate a change in tertiary structure of the mutants. Far UV circular dichroism spectra suggest altered packing of the secondary structural elements. Gel permeation chromatography reveals polydispersity for both of the mutant proteins. An appreciable increase in the molecular mass of the mutant alphaA crystallin is also observed. However, the change in oligomer size of the alphaB mutant is less significant. These results suggest that the conserved arginine of the alpha-crystallin domain of the small heat shock proteins is essential for their structural integrity and subsequent in vivo function.     

Mechanism of insolubilization by a single-point mutation in alphaA-crystallin linked with hereditary human cataracts

AlphaA-crystallin is a small heat shock protein that functions as a molecular chaperone and a lens structural protein. The R49C single-point mutation in alphaA-crystallin causes hereditary human cataracts. We have previously investigated the in vivo properties of this mutant in a gene knock-in mouse model. Remarkably, homozygous mice carrying the alphaA-R49C mutant exhibit nearly complete lens opacity concurrent with small lenses and small eyes. Here we have investigated the 90 degrees light scattering, viscosity, refractive index, and bis-ANS fluorescence of lens proteins isolated from the alphaA-R49C mouse lenses and found that the concentration of total water-soluble proteins showed a pronounced decrease in alphaA-R49C homozygous lenses. Light scattering measurements on proteins separated by gel permeation chromatography showed a small amount of high-molecular mass aggregated material in the void volume which still remains soluble in alphaA-R49C homozygous lens homogenates. An increased level of binding of beta- and gamma-crystallin to the alpha-crystallin fraction was observed in alphaA-R49C heterozygous and homozygous lenses but not in wild-type lenses. Quantitative analysis with the hydrophobic fluorescence probe bis-ANS showed a pronounced increase in fluorescence yield upon binding to alpha-crystallin from mutant as compared with the wild-type lenses. These results suggest that the decrease in the solubility of the alphaA-R49C mutant protein was due to an increase in its hydrophobicity and supra-aggregation of alphaA-crystallin that leads to cataract formation. Our study further shows that analysis of mutant proteins from the mouse model is an effective way to understand the mechanism of protein insolubilization in hereditary cataracts.     

Cataract mutation P20S of alphaB-crystallin impairs chaperone activity of alphaA-crystallin and induces apoptosis of human lens epithelial cells

Cataract is a common cause of childhood blindness worldwide. alpha-crystallin, which is comprised of two homologous subunits, alphaA- and alphaB-crystallin, plays a key role in the maintenance of lens transparency. Recently, we have identified a missense mutation in alphaB-crystallin that changes the proline residue at codon 20 to a serine residue (P20S) in a large Chinese family with autosomal dominant posterior polar congenital cataract. To explore the molecular mechanism by which the P20S mutation causes cataract, we examined the quaternary structure, subunit exchange and chaperone activity of the reconstituted heteroaggregates of alpha-crystallins containing wild type (WT) alphaA in combination with either WT-alphaB- or mutant alphaB-crystallin, respectively. Compared with heteroaggregates of WT-alphaA and WT-alphaB, heteroaggregates containing WT-alphaA and mutant alphaB showed nearly the same molecular mass, but the subunit-exchange rate and chaperone activity were decreased markedly. In human lens epithelial cells, unlike WT-alphaB-crystallin, the P20S mutant protein showed abnormal nuclear localization, and unusual ability to trigger apoptosis. These results suggest that the changes in the structure and function of the alpha-crystallin complex and cytotoxicity are vital factors in the pathogenesis of congenital cataract linked to the P20S mutation in the alphaB-crystallin.     

Role of the non-enzymatic glycosylation of protein in the formation of human cataracts

We have measured the free epsilon amino groups in soluble and insoluble proteins of clear human lenses and diabetic and non-diabetic senile cataractous lenses. The free epsilon amino groups content of soluble and insoluble proteins was significantly lower in diabetic cataracts than in clear lenses and non diabetic senile cataracts. Our results seem to demonstrate that non-enzymatic glycosylation of lens protein could play a role in the pathogenesis of cataract in diabetes.