Pathogenic mechanism of congenital cataract caused by the CRYBA1/A3-G91del variant and related intervention strategies.

Congenital cataracts, which are genetically heterogeneous eye disorders, lead to visual impairment in childhood. In our previous study, we identified a novel mutation in exon 4 of the CRYBA1/BA3 gene, which resulted in the deletion of a highly conserved glycine at codon 91 (G91del) and perinuclear zonular cataract. The G91del variant is one of the most frequent pathogenic mutations in CRYBA1/BA3; however, its pathogenic mechanism remains unclear. In this study, we purified ßA3-crystallin and the ßA3-G91del variant. ßA3-G91del was prone to proteolysis and exhibited very low solubility and low structural stability. Next, we constructed a CRYBA1/BA3 mutant cell model and observed that G91del mutant proteins were more sensitive to environmental stress and prone to form aggregates. Size-exclusion chromatography and molecular dynamics simulation showed that the G91del mutation impaired the ability of ßA3 to form homo-oligomers. In addition, the protein folding process of ßA3-G91del was complicated and showed more intermediate states, resulting in amyloid fiber aggregation and induction of cellular apoptosis. Finally, we investigated intervention strategies for congenital cataract caused by the CRYBA1/A3-G91del variant. The addition of lanosterol reversed the negative effects of the G91del mutation under external stress. This study may help explore potential treatment strategies for related cataracts.

In silico analysis and high-risk pathogenic phenotype predictions of non-synonymous single nucleotide polymorphisms in human Crystallin beta A4 gene associated with congenital cataract.

In order to provide a cost-effective method to narrow down the number of pathogenic Crystallin beta A4 (CRYBA4) non-synonymous single nucleotide polymorphisms (nsSNPs), we collected nsSNP information of the CRYBA4 gene from SNP databases and literature, predicting the pathogenicity and possible changes of protein properties and structures using multiple bioinformatics tools. The nsSNP data of the CRYBA4 gene were collected from 4 databases and published literature. According to 12 criteria, six bioinformatics tools were chosen to predict the pathogenicity. I-Mutant 2.0, Mupro and INPS online tools were used to analyze the effects of amino acid substitution on protein stability by calculating the value of ΔΔG. ConSurf, SOPMA, GETAREA and HOPE online tools were used to predict the evolutionary conservation of amino acids, solvent accessible surface areas, and the physical and chemical properties and changes of protein structure. All 157 CRYBA4 nsSNPs were analyzed. Forty-four CRYBA4 high-risk pathogenic nsSNPs (predicted to be pathogenic by all six software tools) were detected out of the 157 CRYBA4 nsSNPs, four of which (c.283C>T, p.R95W; c.449T>A, p.V150D; c.475G>A, p.G159R; c.575G>C, p.R192P) should be focused on because of their high potential pathogenicity and possibility of changing protein properties. Thirty high-risk nsSNPs were predicted to cause a decrease of protein stability. Twenty-nine high-risk nsSNPs occurred in evolutionary conserved positions. Twenty-two high-risk nsSNPs occurred in the core of the protein. It is predicted that these high-risk pathogenic nsSNPs can cause changes in the physical and chemical properties of amino acids, resulting in structural changes of proteins and changes in the interactions between domains and other molecules, thus affecting the function of proteins. This study provides important reference value when narrowing down the number of pathogenic CRYBA4 nsSNPs and studying the pathogenesis of congenital cataracts. By using this method, we can easily find 44 high-risk pathogenic nsSNPs out of 157 CRYBA4 nsSNPs.

Hotspots of age-related protein degradation: the importance of neighboring residues for the formation of non-disulfide crosslinks derived from cysteine.

Over time, the long-lived proteins that are present throughout the human body deteriorate. Typically, they become racemized, truncated, and covalently cross-linked. One reaction responsible for age-related protein cross-linking in the lens was elucidated recently and shown to involve spontaneous formation of dehydroalanine (DHA) intermediates from phosphoserine. Cys residues are another potential source of DHA, and evidence for this was found in many lens crystallins. In the human lens, some sites were more prone to forming non-disulfide covalent cross-links than others. Foremost among them was Cys5 in ßA4 crystallin. The reason for this enhanced reactivity was investigated using peptides. Oxidation of Cys to cystine was a prerequisite for DHA formation, and DHA production was accelerated markedly by the presence of a Lys, one residue separated from Cys5. Modeling and direct investigation of the N-terminal sequence of ßA4 crystallin, as well as a variety of homologous peptides, showed that the epsilon amino group of Lys can promote DHA production by nucleophilic attack on the alpha proton of cystine. Once a DHA residue was generated, it could form intermolecular cross-links with Lys and Cys. In the lens, the most abundant cross-link involved Cys5 of ßA4 crystallin attached via a thioether bond to glutathione. These findings illustrate the potential of Cys and disulfide bonds to act as precursors for irreversible covalent cross-links and the role of nearby amino acids in creating 'hotpsots' for the spontaneous processes responsible for protein degradation in aged tissues.

Congenital microcornea-cataract syndrome-causing mutation X253R increases ßB1-crystallin hydrophobicity to promote aggregate formation.

The high solubility and lifelong stability of crystallins are crucial to the maintenance of lens transparency and optical properties. Numerous crystallin mutations have been linked to congenital cataract, which is one of the leading causes of newborn blindness. Besides cataract, several crystallin mutations have also been linked to syndromes such as congenital microcornea-cataract syndrome (CMCC). However, the molecular mechanism of CMCC caused by crystallin mutations remains elusive. In the present study, we investigated the mechanism of CMCC caused by the X253R mutation in ßB1-crystallin. The exogenously expressed X253R proteins were prone to form p62-negative aggregates in HeLa cells, strongly inhibited cell proliferation and induced cell apoptosis. The intracellular X253R aggregates could be successfully redissolved by lanosterol but not cholesterol. The extra 26 residues at the C-terminus of ßB1-crystallin introduced by the X253R mutation had little impact on ßB1-crystallin structure and stability, but increased ßB1-crystallin hydrophobicity and decreased its solubility. Interestingly, the X253R mutant fully abolished the aggregatory propensity of ßB1- and ßA3/ßB1-crystallins at high temperatures, suggesting that X253R was an aggregation-inhibition mutation of ß-crystallin homomers and heteromers in dilute solutions. Our results suggest that an increase in hydrophobicity and a decrease in solubility might be responsible for cataractogenesis induced by the X253R mutation, while the cytotoxic effect of X253R aggregates might contribute to the defects in ocular development. Our results also highlight that, at least in some cases, the aggregatory propensity in dilute solutions could not fully mimic the behaviours of mutated proteins in the crowded cytoplasm of the cells.

Interaction of ßA3-Crystallin with Deamidated Mutants of αA- and αB-Crystallins.

Interaction among crystallins is required for the maintenance of lens transparency. Deamidation is one of the most common post-translational modifications in crystallins, which results in incorrect interaction and leads to aggregate formation. Various studies have established interaction among the α- and ß-crystallins. Here, we investigated the effects of the deamidation of αA- and αB-crystallins on their interaction with ßA3-crystallin using surface plasmon resonance (SPR) and fluorescence lifetime imaging microscopy-fluorescence resonance energy transfer (FLIM-FRET) methods. SPR analysis confirmed adherence of WT αA- and WT αB-crystallins and their deamidated mutants with ßA3-crystallin. The deamidated mutants of αA-crystallin (αA N101D and αA N123D) displayed lower adherence propensity for ßA3-crystallin relative to the binding affinity shown by WT αA-crystallin. Among αB-crystallin mutants, αB N78D displayed higher adherence propensity whereas αB N146D mutant showed slightly lower binding affinity for ßA3-crystallin relative to that shown by WT αB-crystallin. Under the in vivo condition (FLIM-FRET), both αA-deamidated mutants (αA N101D and αA N123D) exhibited strong interaction with ßA3-crystallin (32±4% and 36±4% FRET efficiencies, respectively) compared to WT αA-crystallin (18±4%). Similarly, the αB N78D and αB N146D mutants showed strong interaction (36±4% and 22±4% FRET efficiencies, respectively) with ßA3-crystallin compared to 18±4% FRET efficiency of WT αB-crystallin. Further, FLIM-FRET analysis of the C-terminal domain (CTE), N-terminal domain (NTD), and core domain (CD) of αA- and αB-crystallins with ßA3-crystallin suggested that interaction sites most likely reside in the αA CTE and αB NTD regions, respectively, as these domains showed the highest FRET efficiencies. Overall, results suggest that similar to WT αA- and WTαB-crystallins, the deamidated mutants showed strong interactionfor ßA3-crystallin. Variable in vitro and in vivo interactions are most likely due to the mutant's large size oligomers, reduced hydrophobicity, and altered structures. Together, the results suggest that deamidation of α-crystallin may facilitate greater interaction and the formation of large oligomers with other crystallins, and this may contribute to the cataractogenic mechanism.

Effect of Ca2+ and Mg2+ ions on oligomeric state and chaperone-like activity of αB-crystallin in crowded media.

The main function of small heat shock proteins acting as suppressors of aggregation of non-native proteins is greatly influenced by crowded environment in the cell and the presence of divalent metal ions. The goal of the present work was to study the effects of Ca(2+) and Mg(2+) ions on the quaternary structure and anti-aggregation activity of αB-crystallin under crowding conditions. We showed that Ca(2+) and Mg(2+) ions induced formation of suboligomeric forms of αB-crystallin. This effect was retained in the presence of crowder (polyethylene glycol), although to a lesser degree. The chaperone-like activity of αB-crystallin was analyzed using heat-induced aggregation of myosin subfragment 1 (S1) at 40°C. In the absence of crowding agents chaperone-like activity of αB-crystallin exhibited low sensitivity to the presence of Ca(2+) and Mg(2+) ions. The addition of the crowding agents (polyethylene glycol 20000, Ficoll 70) dramatically increased S1 aggregation rates and significantly depressed anti-aggregation activity of αB-crystallin. Low concentrations of Ca(2+) (0.1mM) and Mg(2+) (10mM) partially restored the chaperone-like activity of αB-crystallin in the presence of crowders. This effect was observed at relatively low values of [αB-crystallin]/[S1] molar ratio, however, at [αB-crystallin]/[S1]>0.2 the stimulating effect of Ca(2+) became less pronounced. These findings might indicate that under crowded cell conditions different factors, including divalent cations, can effectively modulate chaperone-like activity of protein chaperones, which otherwise cannot properly cope with crowding-provoked accelerated rates of substrates aggregation.

Alpha B- and ßA3-crystallins containing d-aspartic acids exist in a monomeric state.

Crystallin stability and subunit-subunit interaction are essential for eye lens transparency. There are three types of crystallins in lens, designated as α-, ß-, and γ-crystallins. Alpha-crystallin is a hetero-polymer of about 800kDa, consisting of 35-40 subunits of two different αA- and αB-subunits, each of 20kDa. The ß/γ-crystallin superfamily comprises oligomeric ß-crystallin (2-6 subunits) and monomeric γ-crystallin. Since lens proteins have very long half-lives, they undergo numerous post-translational modifications including racemization, isomerization, deamidation, oxidation, glycation, and truncation, which may decrease crystallin solubility and ultimately cause cataract formation. Racemization and isomerization of aspartyl (Asp) residues have been detected only in polymeric α- and oligomeric ß-crystallin, while the situation in monomeric γ-crystallin has not been studied. Here, we investigated the racemization and isomerization of Asp in the γ-crystallin fraction of elderly donors. The results show that Asp residues of γS-, γD- and γC-crystallins were not racemized and isomerized. However, strikingly, we found that a portion of αB-crystallin and ßA3-crystallin moved to the lower molecular weight fraction which is the same size of γ-crystallin. In those fractions, Asp-96 of αB-crystallin and Asp-37 of ßA3-crystallin were highly inverted, which do not occur in the native lens higher molecular weight fraction. Our results indicate the possibility that the inversion of Asp residues may induce dissociation of αB- and ßA3-crystallins from the polymeric and oligomeric states. This is the first report that stereoinversion of amino acids disturbs lens protein assembly in aged human lens.

ßB1-crystallin: thermodynamic profiles of molecular interactions.

BACKGROUND: ß-Crystallins are structural proteins maintaining eye lens transparency and opacification. Previous work demonstrated that dimerization of both ßA3 and ßB2 crystallins (ßA3 and ßB2) involves endothermic enthalpy of association (∼8 kcal/mol) mediated by hydrophobic interactions. METHODOLOGY/PRINCIPAL FINDINGS: Thermodynamic profiles of the associations of dimeric ßA3 and ßB1 and tetrameric ßB1/ßA3 were measured using sedimentation equilibrium. The homo- and heteromolecular associations of ßB1 crystallin are dominated by exothermic enthalpy (-13.3 and -24.5 kcal/mol, respectively). CONCLUSIONS/SIGNIFICANCE: Global thermodynamics of ßB1 interactions suggest a role in the formation of stable protein complexes in the lens via specific van der Waals contacts, hydrogen bonds and salt bridges whereas those ß-crystallins which associate by predominately hydrophobic forces participate in a weaker protein associations.

The benefits of being ß-crystallin heteromers: ßB1-crystallin protects ßA3-crystallin against aggregation during co-refolding.

ß-Crystallins are the major structural proteins in mammalian lens, and their stability is critical in maintaining the transparency and refraction index of the lens. Among the seven ß-crystallins, ßA3-crystallin and ßB1-crystallin, an acidic and a basic ß-crystallin, respectively, can form heteromers in vivo. However, the physiological roles of the heteromer have not been fully elucidated. In this research, we studied whether the basic ß-crystallin facilitates the folding of acidic ß-crystallin. Equilibrium folding studies revealed that the ßA3-crystallin and ßB1-crystallin homomers and the ßA3/ßB1-crystallin heteromer all undergo similar five-state folding pathways which include one dimeric and two monomeric intermediates. ßA3-Crystallin was found to be the most unstable among the three proteins, and the transition curve of ßA3/ßB1-crystallin was close to that of ßB1-crystallin. The dimeric intermediate may be a critical determinant in the aggregation process and thus is crucial to the lifelong stability of the ß-crystallins. A comparison of the Gibbs free energy of the equilibrium folding suggested that the formation of heteromer contributed to the stabilization of the dimer interface. On the other hand, ßA3-crystallin, the only protein whose refolding is challenged by serious aggregation, can be protected by ßB1-crystallin in a dose-dependent manner during the kinetic co-refolding. However, the protection is not observed in the presence of the pre-existed well-folded ßB1-crystallin. These findings suggested that the formation of ß-crystallin heteromers not only stabilizes the unstable acidic ß-crystallin but also protects them against aggregation during refolding from the stress-denatured states.

A novel mutation in CRYBB1 associated with congenital cataract-microcornea syndrome: the p.Ser129Arg mutation destabilizes the ßB1/ßA3-crystallin heteromer but not the ßB1-crystallin homomer.

Congenital cataract-microcornea syndrome (CCMC) is a clinically and genetically heterogeneous condition characterized by lens opacities and microcornea. It appears as a distinct phenotype of heritable congenital cataract. Here we report a large Chinese family with autosomal dominant congenital cataract and microcornea. Evidence for linkage was detected at marker D22S1167 (LOD score [Z]=4.49, recombination fraction [θ]=0.0), which closely flanks the â-crystallin gene cluster locus. Direct sequencing of the candidate âB1-crystallin gene (CRYBB1) revealed a c.387C>A transversion in exon 4, which cosegregated with the disease in the family and resulted in the substitution of serine by arginine at codon 129 (p.Ser129Arg). A comparison of the biophysical properties of the recombinant ß-crystallins revealed that the mutation impaired the structures of both ßB1-crystallin homomer and ßB1/ßA3-crystallin heteromer. More importantly, the mutation significantly decreased the thermal stability of ßB1/ßA3-crystallin but not ßB1-crystallin. These findings highlight the importance of protein-protein interactions among ß-crystallins in maintaining lens transparency, and provide a novel insight into the molecular mechanism underlying the pathogenesis of human CCMC.

A missense mutation in CRYBA4 associated with congenital cataract and microcornea.

PURPOSE: To identify mutations in a Chinese family with congenital cataract and microcornea. METHODS: Detailed family history and clinical data were recorded. Genomic DNA was extracted from leukocytes of venous blood of the patients and noncarriers in this family along with 100 normal individuals. All six exons of crystallin, beta A4 gene (CRYBA4) were amplified by PCR methods and direct sequencing. RESULTS: We identified a c.225G>T sequence change that led to an amino acid substitution G64W in the CRYBA4-induced protein in two patients of this family; this nucleotide substitution was not detected in the other individuals. CONCLUSIONS: A novel missense mutation in CRYBA4 was identified in our study. It expands the mutation spectrum of CRYBA4 and provides useful information to the study of molecular pathogenesis of cataract and microcornea.

Decreasing the homodimer interaction: a common mechanism shared by the deltaG91 mutation and deamidation in betaA3-crystallin.

PURPOSE: Cataracts can be broadly divided into two types: congenital cataracts and age-related cataracts. DeltaG91 is a previously discovered congenital mutation in betaA3-crystallin that impairs protein solubility. On the other hand, the deamidation of beta-crystallin is a significant feature in aged and cataractous lenses. Several deamidation sites were also identified in betaA3-crystallin. The present study is to compare the functional consequence of DeltaG91 mutation and the deamidation of betaA3-crystallin in terms of folding properties and protein-protein interaction. METHODS: Protein secondary structure and hydrophobic properties were investigated by in silica analysis of the wild type and mutants sequences. Full-length betaA3-crystallin was cloned into a mammalian two-hybrid system in order to investigate protein-protein interactions. Deletion and deamidation were introduced by site-directed mutagenesis protocols. Both the Q85 and Q180 deamidation sites were substituted with glutamic acid residues to mimic deamidation. Different combinations of plasmid constructs were transfected in HeLa cells, and changes of protein-protein interactions were analyzed by the luciferase assay. RESULTS: Bioinformatics prediction suggested that DeltaG91 mutation alters both the predicted secondary structure and hydrophobic character of betaA3-crystallin, while deamidation only exhibits minimal effects. Mammalian two-hybrid results indicated that both DeltaG91 mutation and Q85/Q180 deamidation could significantly decrease the interaction of the betaA3-crystallin homodimer. CONCLUSION: Our results provided evidence that both mutations involved in congenital cataracts and deamidation in aged lenses commonly altered protein-protein interaction between human lens betaA3-crystallins, which may lead to protein insolubilization and contribute to cataracts.

N-terminal extension of beta B1-crystallin: identification of a critical region that modulates protein interaction with beta A3-crystallin.

The human lens proteins beta-crystallins are subdivided into acidic (betaA1-betaA4) and basic (betaB1-betaB3) subunit groups. These structural proteins exist at extremely high concentrations and associate into oligomers under physiological conditions. Crystallin acidic-basic pairs tend to form strong heteromolecular associations. The long N-terminal extensions of beta-crystallins may influence both homo- and heteromolecular interactions. However, identification of the critical regions of the extensions mediating protein associations has not been previously addressed. This was studied by comparing the self-association and heteromolecular associations of wild-type recombinant betaA3- and betaB1-crystallins and their N-terminally truncated counterparts (betaA3DeltaN30 and betaB1DeltaN56) using several biophysical techniques, including analytical ultracentrifugation and fluorescence spectroscopy. Removal of the N-terminal extension of betaA3 had no effect on dimerization or heteromolecular tetramer formation with betaB1. In contrast, the level of self-association of betaB1DeltaN56 increased, resulting in homotetramer formation, and heteromolecular association with betaA3 was blocked. Limited proteolysis of betaB1 produced betaB1DeltaN47, which is similar to intact protein formed dimers but in contrast showed enhanced heteromolecular tetramer formation with betaA3. The tryptic digestion was physiologically significant, corresponding to protease processing sites observed in vivo. Molecular modeling of the N-terminal betaB1 extension indicates structural features that position a mobile loop in the vicinity of these processing sites. The loop is derived from residues 48-56 which appear to be critical for mediating protein interactions with betaA3-crystallin.

Truncated human betaB1-crystallin shows altered structural properties and interaction with human betaA3-crystallin.

The purpose of the study was to determine the effects of truncation of various regions of betaB1-crystallin on its structural properties and stability of heterooligomers formed by wild-type (WT) betaB1 or its deletion mutants with WT betaA3-crystallin. For these analyses, seven deletion mutants of betaB1-crystallin were generated with the following sequential deletions of either N-terminal arm [betaB1(59-252)], N-terminal arm + motif I [betaB1(99-252)], N-terminal arm + motif I + motif II [betaB1(144-252)], N-terminal arm + motif I + motif II + connecting peptide [betaB1(149-252)], C-terminal extension [betaB1(1-234)], C-terminal extension plus motif IV [betaB1(1-190)], or C-terminal extension + motif III + motif IV [betaB1(1-148)]. The betaB1-crystallin became water insoluble on the deletion of C-terminal extension and subsequent deletions of the C-terminal domain (C-terminal extension plus motifs III and IV) while it remained partially soluble on the deletion of the N-terminal domain (N-terminal arm plus motifs I and II). However, circular dichroism spectral analysis showed that the deletion of the N-terminal domain but not the C-terminal domain exhibited relatively greater structural changes in the crystallin. The deletion of the C-terminal domain resulted in a greater exposure and disturbance in the microenvironment of Trp-100, Trp-123, and Trp-126 (localized in the motif II), suggesting a relatively greater role of the C-terminal domain than the N-terminal domain in the structural stability of the crystallin. The deletion of the N-terminal extension in betaB1 resulted in maximum exposure of hydrophobic patches and compact structure and in a maximum loss of subunit exchange with WT betaA3-crystallin compared to deletion of either the C-terminal extension, the N-terminal domain, or the C-terminal domain. The thermal stability results of the heterooligomer of betaB1- plus betaA3-crystallins suggested that oligomers lose their stability on deletion of the C-terminal domain. Together, the results suggested that the N-terminal arm of betaB1-crystallin plays a major role in interaction with betaA3-crystallin during heterooligomer formation, and the solubility of betaB1-crystallin per se and that of the heterooligomer with betaA3-crystallin are dependent on the intact C-terminal domain of betaB1-crystallin.

Identification of interaction sites between human betaA3- and alphaA/alphaB-crystallins by mammalian two-hybrid and fluorescence resonance energy transfer acceptor photobleaching methods.

Our recent study has shown that betaA3-crystallin along with betaB1- and betaB2-crystallins were part of high molecular weight complex obtained from young, old, and cataractous lenses suggesting potential interactions between alpha- and beta-crystallins (Srivastava, O. P., Srivastava, K., and Chaves, J. M. (2008) Mol. Vis. 14, 1872-1885). To investigate this further, this study was carried out to determine the interaction sites of betaA3-crystallin with alphaA- and alphaB-crystallins. The study employed a mammalian two-hybrid method, an in vivo assay to determine the regions of betaA3-crystallin that interact with alphaA- and alphaB-crystallins. Five regional truncated mutants of betaA3-crystallin were generated using specific primers with deletions of N-terminal extension (NT) (named betaA3-NT), N-terminal extension plus motif I (named betaA3-NT + I), N-terminal extension plus motifs I and II (named betaA3-NT + I + II), motif III plus IV (named betaA3-III + IV), and motif IV (named betaA3-IV). The mammalian two-hybrid studies were complemented with fluorescence resonance energy transfer acceptor photobleaching studies using the above described mutant proteins, fused with DsRed (Red) and AcGFP fluorescent proteins. The results showed that the motifs III and IV of betaA3-crystallin were interactive with alphaA-crystallin, and motifs II and III of betaA3-crystallin primarily interacted with alphaB-crystallin.

Deamidation alters interactions of beta-crystallins in hetero-oligomers.

PURPOSE: Cataracts are a major cause of blindness worldwide. A potential mechanism for loss of visual acuity may be due to light scattering from disruption of normal protein-protein interactions. During aging, the lens accumulates extensively deamidated crystallins. We have previously reported that deamidation in the betaA3-crystallin (betaA3) dimer decreased the stability of the dimer in vitro. The purpose of the present study was to investigate if deamidation altered the interaction of betaA3 with other beta-crystallin subunits. METHODS: Deamidation was mimicked by replacing glutamines, Q85 and Q180, at the predicted interacting interface between betaA3 domains with glutamic acids by site-directed mutagenesis. Human recombinant wild type betaA3 or the doubly deamidated mutant betaA3 Q85E/Q180E (DM betaA3) were mixed with either betaB1- or betaB2-crystallin (betaB1 or betaB2) subunits. After incubation at increasing temperatures, hetero-oligomers were resolved from individual subunits and their molar masses determined by size exclusion chromatography with in line multiangle laser light scattering. Structural changes of hetero-oligomers were analyzed with fluorescence spectroscopy and blue-native PAGE. RESULTS: Molar masses of the hetero-oligomer complexes indicated betaA3 formed a polydispersed hetero-tetramer with betaB1 and a mondispersed hetero-dimer with betaB2. Deamidation at the interface in the betaA3 dimer decreased formation of the hetero-oligomer with betaB1 and further decreased formation of the hetero-dimer with betaB2. During thermal-induced denaturation of the deamidated betaA3 dimer, betaB1 but not betaB2 was able to prevent precipitation of betaA3. CONCLUSIONS: Deamidation decreased formation of hetero-oligomers between beta-crystallin subunits. An excess accumulation of deamidated beta-crystallins in vivo may disrupt normal protein-protein interactions and diminish the stabilizing effects between them, thus, contributing to the accumulation of insoluble beta-crystallins during aging and cataracts.

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.

Isolation and characterization of betaA3-crystallin associated proteinase from alpha-crystallin fraction of human lenses.

PURPOSE: The purpose was to characterize the properties of a proteinase activity associated with betaA3-crystallin, which was isolated from the alpha-crystallin fraction of human lenses. METHODS: An inactive, Arg-bond hydrolyzing proteinase in the alpha-crystallin fraction, which was isolated from the water soluble (WS) protein fraction of 60- to 70-year-old human lenses, was activated by sodium deoxycholate treatment. The activated enzyme was purified by a three-step procedure that included a size-exclusion Agarose A1.5 m chromatography, non-denaturing preparative gel-electrophoresis, and size-exclusion HPLC. The purified proteinase was characterized for the proteinase type, proteolysis of bovine recombinant gammaB-, gammaC-, and gammaD-crystallins, and its presence in three different protein fractions of human lenses (i.e., alpha-crystallin, beta(H)-crystallin, and membrane fractions). RESULTS: An inactive, Arg-bond hydrolyzing proteinase present in the alpha-crystallin fraction showed activity on treatment with detergents such as sodium deoxycholate, Triton X-100, octyl beta-D-glucopyranoside, and CHAPS (3-[(3-cholamido propyl) dimethylammonio]-1-propanesulfonate). The sodium deoxycholate-activated enzyme was released from the alpha-crystallin fraction since it eluted at a lower molecular weight species than alpha-crystallin during size-exclusion Agarose A1.5 m chromatography. Following a three-step purification procedure, the enzyme showed three species between 22 kDa and 25 kDa during sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) analysis. The three protein bands were identified as betaA3-, betaB1-, and betaB2-crystallin by the matrix-assisted laser desorption/ionization-time of flight (MALDI-TOF) and tandem mass spectrometric (ES-MS/MS) methods. Inhibitor studies revealed that the enzyme was a serine-type proteinase. Among the recombinant betaA3-, betaB1-, or betaB2-crystallins, only the betaA3-crystallin exhibited the proteinase activity following detergent treatment and size-exclusion chromatography. The proteinase also exhibited proteolysis of gammaC- and gammaD- crystallins, and the cleavage of gammaD-crystallin at M(1)-G(2), Q(54)-Y(55), M(70)-G(71), and Q(103)-M(104) bonds. Further, the enzyme was also present in three fractions of human lenses (alpha-crystallin, beta(H)-crystallin, and membrane fractions). CONCLUSIONS: A serine-type betaA3-crystallin proteinase existed in an inactive state in the alpha-crystallin fraction and was activated by detergents. The enzyme proteolyzed alphaA-, alphaB-, gammaC-, and gammaD-crystallins and was present in three fractions (alpha-crystallin, beta(H)-crystallin, and membrane-fractions) of 60 to 70-year-old human lenses.

Deamidation destabilizes and triggers aggregation of a lens protein, betaA3-crystallin.

Protein aggregation is a hallmark of several neurodegenerative diseases and also of cataracts. The major proteins in the lens of the eye are crystallins, which accumulate throughout life and are extensively modified. Deamidation is the major modification in the lens during aging and cataracts. Among the crystallins, the betaA3-subunit has been found to have multiple sites of deamidation associated with the insoluble proteins in vivo. Several sites were predicted to be exposed on the surface of betaA3 and were investigated in this study. Deamidation was mimicked by site-directed mutagenesis at Q42 and N54 on the N-terminal domain, N133 and N155 on the C-terminal domain, and N120 in the peptide connecting the domains. Deamidation altered the tertiary structure without disrupting the secondary structure or the dimer formation of betaA3. Deamidations in the C-terminal domain and in the connecting peptide decreased stability to a greater extent than deamidations in the N-terminal domain. Deamidation at N54 and N155 also disrupted the association with the betaB1-subunit. Sedimentation velocity experiments integrated with high-resolution analysis detected soluble aggregates at 15%-20% in all deamidated proteins, but not in wild-type betaA3. These aggregates had elevated frictional ratios, suggesting that they were elongated. The detection of aggregates in vitro strongly suggests that deamidation may contribute to protein aggregation in the lens. A potential mechanism may include decreased stability and/or altered interactions with other beta-subunits. Understanding the role of deamidation in the long-lived crystallins has important implications in other aggregation diseases.

Deamidation alters the structure and decreases the stability of human lens betaA3-crystallin.

According to the World Health Organization, cataracts account for half of the blindness in the world, with the majority occurring in developing countries. A cataract is a clouding of the lens of the eye due to light scattering of precipitated lens proteins or aberrant cellular debris. The major proteins in the lens are crystallins, and they are extensively deamidated during aging and cataracts. Deamidation has been detected at the domain and monomer interfaces of several crystallins during aging. The purpose of this study was to determine the effects of two potential deamidation sites at the predicted interface of the betaA3-crystallin dimer on its structure and stability. The glutamine residues at the reported in vivo deamidation sites of Q180 in the C-terminal domain and at the homologous site Q85 in the N-terminal domain were substituted with glutamic acid residues by site-directed mutagenesis. Far-UV and near-UV circular dichroism spectroscopy indicated that there were subtle differences in the secondary structure and more notable differences in the tertiary structure of the mutant proteins compared to that of the wild type betaA3-crystallin. The Q85E/Q180E mutant also was more susceptible to enzymatic digestion, suggesting increased solvent accessibility. These structural changes in the deamidated mutants led to decreased stability during unfolding in urea and increased precipitation during heat denaturation. When simulating deamidation at both residues, there was a further decrease in stability and loss of cooperativity. However, multiangle-light scattering and quasi-elastic light scattering experiments showed that dimer formation was not disrupted, nor did higher-order oligomers form. These results suggest that introducing charges at the predicted domain interface in the betaA3 homodimer may contribute to the insolubilization of lens crystallins or favor other, more stable, crystallin subunit interactions.