Heteromeric formation with ßA3 protects the low thermal stability of ßB1-L116P.

BACKGROUND/AIMS: Congenital cataract is the leading cause of visual disability and blindness in childhood. ßB1-crystallin (CRYBB1) comprises about 1/10th of crystallin structural proteins, forming heteromers to maintain lens transparency. We previously reported a CRYBB1 mutation (c.347T>C, p.L116P) affecting 16 patients in a congenital nuclear cataract family. In this study, we investigate the underlying pathogenic mechanism of ßB1-L116P. METHODS: Protein isolation, size-exclusion chromatography, spectroscopy, Uncle stability screens and molecular dynamics simulations were used to assess ßA3- and ßB1-crystallin thermal stability, structural properties and heteromer formation. RESULTS: Cells that overexpressed ßB1-L116P tended to form aggregates and precipitations under heat-shock stress. Thermal denaturation and time-dependent turbidity experiments showed that thermal stability was significantly impaired. Moreover, protein instability appeared to increase with elevated concentrations detected by the Uncle system. Additionally, ßA3 had a relative protective effect on ßB1-L116P after heteromers were formed, although ßA3 was relatively unstable and was usually protected by basic ß-crystallins. Molecular dynamic simulations revealed that L116P mutation altered the hydrophobic residues at the surface around the mutant site, providing solvents more access to the internal and hydrophobic parts of the protein. CONCLUSIONS: Decreased ßB1-crystallin thermal stability in the presence of the cataract-related L116P mutation contributes significantly to congenital cataract formation. Moreover, its formation of heteromers with ßA3 protects against the low thermal stability of ßB1-L116P.

A novel missense mutation of CRYBA1 in a northern Chinese family with inherited coronary cataract with blue punctate opacities.

PURPOSE: To demonstrate the underlying genetic defect that contribute to inherited cataract in a northern Chinese pedigree. METHODS: The study recruited a family pedigree with a diagnosis of bilateral coronary cataract with blue punctate opacities. Fourteen family members and 100 healthy volunteers were enrolled. DNA sample of the proband in this family were analyzed by high-throughput sequencing, which was then demonstrated by Sanger sequencing in the remained people in the family and 100 controls. The functional effect of mutant genes was investigated via bioinformatics analysis, including Polymorphism Phenotyping version2 (PolyPhen-2), Protein Variation Effect Analyzer (PROVEAN v1.1.3) Scale-Invariant Feature Transform (SIFT), and Mutation Taster. RESULTS: In this three-generation family, a novel heterozygous mutation was found in the kinase domain of CRYBA1 gene (c.340C > T, p.R114C), which was only detected in patients in the family with inherited cataract and were not detected in the remained people in the family nor in normal people. The pathogenic effect of the mutation was verified via bioinformatics analysis. CONCLUSION: Our study presented the molecular experiments to confirm that a novel missense mutation of c.340 C > T located in exon 4 of CRYBA1 gene results in a bilateral coronary cataract with blue punctate opacities, which enriches the mutation spectrum of CRYBA1 gene in inherited cataract and deepens the understanding of the pathogenesis of inherited cataract.

ßA3/A1-crystallin regulates apical polarity and EGFR endocytosis in retinal pigmented epithelial cells.

The retinal pigmented epithelium (RPE) is a monolayer of multifunctional cells located at the back of the eye. High membrane turnover and polarization, including formation of actin-based apical microvilli, are essential for RPE function and retinal health. Herein, we demonstrate an important role for ßA3/A1-crystallin in RPE. ßA3/A1-crystallin deficiency leads to clathrin-mediated epidermal growth factor receptor (EGFR) endocytosis abnormalities and actin network disruption at the apical side that result in RPE polarity disruption and degeneration. We found that ßA3/A1-crystallin binds to phosphatidylinositol transfer protein (PITPß) and that ßA3/A1-crystallin deficiency diminishes phosphatidylinositol 4,5-biphosphate (PI(4,5)P2), thus probably decreasing ezrin phosphorylation, EGFR activation, internalization, and degradation. We propose that ßA3/A1-crystallin acquired its RPE function before evolving as a structural element in the lens, and that in the RPE, it modulates the PI(4,5)P2 pool through PITPß/PLC signaling axis, coordinates EGFR activation, regulates ezrin phosphorylation and ultimately the cell polarity.

Modulating EGFR-MTORC1-autophagy as a potential therapy for persistent fetal vasculature (PFV) disease.

Persistent fetal vasculature (PFV) is a human disease that results from failure of the fetal vasculature to regress normally. The regulatory mechanisms responsible for fetal vascular regression remain obscure, as does the underlying cause of regression failure. However, there are a few animal models that mimic the clinical manifestations of human PFV, which can be used to study different aspects of the disease. One such model is the Nuc1 rat model that arose from a spontaneous mutation in the Cryba1 (crystallin, beta 1) gene and exhibits complete failure of the hyaloid vasculature to regress. Our studies with the Nuc1 rat indicate that macroautophagy/autophagy, a process in eukaryotic cells for degrading dysfunctional components to ensure cellular homeostasis, is severely impaired in Nuc1 ocular astrocytes. Further, we show that CRYBA1 interacts with EGFR (epidermal growth factor receptor) and that loss of this interaction in Nuc1 astrocytes increases EGFR levels. Moreover, our data also show a reduction in EGFR degradation in Nuc1 astrocytes compared to control cells that leads to over-activation of the mechanistic target of rapamycin kinase complex 1 (MTORC1) pathway. The impaired EGFR-MTORC1-autophagy signaling in Nuc1 astrocytes triggers abnormal proliferation and migration. The abnormally migrating astrocytes ensheath the hyaloid artery, contributing to the pathogenesis of PFV in Nuc1, by adversely affecting the vascular remodeling processes essential to regression of the fetal vasculature. Herein, we demonstrate in vivo that gefitinib (EGFR inhibitor) can rescue the PFV phenotype in Nuc1 and may serve as a novel therapy for PFV disease by modulating the EGFR-MTORC1-autophagy pathway. ABBREVIATIONS: ACTB: actin, beta; CCND3: cyclin 3; CDK6: cyclin-dependent kinase 6; CHQ: chloroquine; COL4A1: collagen, type IV, alpha 1; CRYBA1: crystallin, beta A1; DAPI: 4'6-diamino-2-phenylindole; EGFR: epidermal growth factor receptor; GAPDH: glyceraldehyde-3-phosphate dehydrogenase; GFAP: glial fibrillary growth factor; KDR: kinase insert domain protein receptor; MAP1LC3/LC3: microtubule-associated protein 1 light chain 3; MKI67: antigen identified by monoclonal antibody Ki 67; MTORC1: mechanistic target of rapamycin kinase complex 1; PARP: poly (ADP-ribose) polymerase family; PCNA: proliferating cell nuclear antigen; PFV: persistent fetal vasculature; PHPV: persistent hyperplastic primary vitreous; RPE: retinal pigmented epithelium; RPS6: ribosomal protein S6; RPS6KB1: ribosomal protein S6 kinase, polypeptide 1; SQSTM1/p62: sequestome 1; TUBB: tubulin, beta; VCL: vinculin; VEGFA: vascular endothelial growth factor A; WT: wild type.

Bidirectional Analysis of Cryba4-Crybb1 Nascent Transcription and Nuclear Accumulation of Crybb3 mRNAs in Lens Fibers.

Purpose: Crystallin gene expression during lens fiber cell differentiation is tightly spatially and temporally regulated. A significant fraction of mammalian genes is transcribed from adjacent promoters in opposite directions ("bidirectional" promoters). It is not known whether two proximal genes located on the same allele are simultaneously transcribed. Methods: Mouse lens transcriptome was analyzed for paired genes whose transcriptional start sites are separated by less than 5 kbp to identify coexpressed bidirectional promoter gene pairs. To probe these transcriptional mechanisms, nascent transcription of Cryba4, Crybb1, and Crybb3 genes from gene-rich part of chromosome 5 was visualized by RNA fluorescent in situ hybridizations (RNA FISH) in individual lens fiber cell nuclei. Results: Genome-wide lens transcriptome analysis by RNA-seq revealed that the Cryba4-Crybb1 pair has the highest Pearson correlation coefficient between their steady-state mRNA levels. Analysis of Cryba4 and Crybb1 nascent transcription revealed frequent simultaneous expression of both genes from the same allele. Nascent Crybb3 transcript visualization in "early" but not "late" differentiating lens fibers show nuclear accumulation of the spliced Crybb3 transcripts that was not affected in abnormal lens fiber cell nuclei depleted of chromatin remodeling enzyme Snf2h (Smarca5). Conclusions: The current study shows for the first time that two highly expressed lens crystallin genes, Cryba4 and Crybb1, can be simultaneously transcribed from adjacent bidirectional promoters and do not show nuclear accumulation. In contrast, spliced Crybb3 mRNAs transiently accumulate in early lens fiber cell nuclei. The gene pairs coexpressed during lens development showed significant enrichment in human "cataract" phenotype.

A novel MAF missense mutation leads to congenital nuclear cataract by impacting the transactivation of crystallin and noncrystallin genes.

The transcription factor v-maf avain musculoaponeurotic fibrosarcoma oncogene homolog (MAF) plays an important role in lens development. It contains a unique extended homology region (EHR) in the DNA binding domain. MAF mutations are associated with phenotypically distinct forms of congenital cataract and show different effects on the transactivation of target genes. Mutations in the MAF EHR region were rarely reported and their corresponding phenotype and impact on target genes' transactivation were not evaluated. A three- generation Chinese family with congenital cataract was recruited. The patients in the family present non-syndromic congenital nuclear and lamellar opacities. A novel MAF mutation (c.812 T > A, p.Val271Glu) was identified by targeted next-generation sequencing. The mutation is in highly conserved EHR region of MAF and co-segregates with the cataract in the family. It is predicted to be pathogenic by multiple algorithms and is absent in a control population. Dual luciferase activity assay shows the mutation significantly impair the transcriptional activity of four crystallin genes (CRYAA, CRYBA4, CRYBA1, and CRYGA) and two non-crystallin genes (HMOX1 and KDELR2). Herein, we report a novel missense mutation in the MAF EHR region of the DNA binding domain in a family with congenital cataract. The mutation is associated with non-syndromic bilateral nuclear cataract and impacts the transactivation of cataract associated genes involved in lens structure and stress response.

Possible association of oestrogen and Cryba4 with masticatory muscle tendon-aponeurosis hyperplasia.

OBJECTIVE: Masticatory muscle tendon-aponeurosis hyperplasia, which is associated with limited mouth opening, progresses very slowly from adolescence. The prevalence rates of this disease are higher among women than among men, suggesting oestrogen involvement. As parafunctional habits are frequently observed, mechanical stress is likely involved in the pathogenesis and advancement of this disease. To elucidate the pathological condition, we examined the effect of oestrogen on tenocyte function and the relationship between mechanical stress and crystallin beta A4 (Cryba4), using murine TT-D6 tenocytes. MATERIALS AND METHODS: Cell proliferation assays, RT-PCR, real-time RT-PCR, Western blot analysis and mechanical loading experiments were performed. RESULTS: The physiological dose of oestrogen increased the levels of scleraxis and tenomodulin in TT-D6 tenocytes. In contrast, forced expression of Cryba4 inhibited scleraxis expression in these cells. Surprisingly, oestrogen significantly promoted cell differentiation in the Cryba4-overexpressing TT-D6 tenocytes. Moreover, tensile force induced Cryba4 expression in these tendon cells. CONCLUSION: Oestrogen and Cryba4 may be associated with the progression of masticatory muscle tendon-aponeurosis hyperplasia.

Partial duplication of the CRYBB1-CRYBA4 locus is associated with autosomal dominant congenital cataract.

Congenital cataract is a rare but severe paediatric visual impediment, often caused by variants in one of several crystallin genes that produce the bulk of structural proteins in the lens. Here we describe a pedigree with autosomal dominant isolated congenital cataract and linkage to the crystallin gene cluster on chromosome 22. No rare single nucleotide variants or short indels were identified by exome sequencing, yet copy number variant analysis revealed a duplication spanning both CRYBB1 and CRYBA4. While the CRYBA4 duplication was complete, the CRYBB1 duplication was not, with the duplicated CRYBB1 product predicted to create a gain of function allele. This association suggests a new genetic mechanism for the development of isolated congenital cataract.

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.

Identification of a De Novo 3bp Deletion in CRYBA1/A3 Gene in Autosomal Dominant Congenital Cataract.

Autosomal dominant congenital cataract (ADCC) is the most common form of inherited cataracts and accounts for one-third of congenital cataracts. Heterozygous null mutations in the crystallin genes are the major cause of the ADCC. This study aims to detect the mutational spectrum of four crystallin genes, CRYBA1/A3, CRYBB1, CRYBB2 and CRYGD in an Iranian family. Genomic DNA was isolated from whole blood cells from theproband and other family members. The coding regions and flanking intronicsequences of crystalline genes were analyzed by Sanger sequencing in aproband with ADCC. The identified mutation was further evaluated in available family members. To predict the potential protein partners of CRYBA1/A3, we also used an in-silico analysis. A de novo heterozygous deletion (c.272-274delGAG, p.G91del) in exon 4 of CRYBA1/A3 gene, leading to a deletion of Glycine at codon 91 was found. This genetic variation did not change the reading frame of CRYBA1 protein. In conclusion, we identified a de novo in-frame 3-bp deletion in the proband with an autosomal dominant congenital cataract, but not in her parents, in an Iranian family. This mutation has occurred de novo on a paternal gamete during spermatogenesis. The in-silico results predicted the interaction of CRYBA1 protein with the other CRY as well as proteins responsible for eye cell signaling.

Differential effect of cataract-associated mutations in MAF on transactivation of MAF target genes.

Three mutations in the highly conserved DNA-binding region of c-MAF (R288P, K297R, and R299S) are associated with phenotypically distinct forms of autosomal dominant congenital cataract. However, the molecular mechanisms underlying this phenotypic diversity remain unclear. In this work, we have investigated the hypothesis that differential transactivation of MAF target genes could be one factor determining the phenotypic differences. Promoter constructs were generated for four human crystallin genes with conserved half-site MAF responsive elements (MARE). MAF expression constructs were constructed with the wildtype MAF sequence and with each of the three known mutations, i.e., R288P (associated with pulverulent cataract), K297R (associated with cerulean cataract), and R299S (associated with the most severe phenotype, congenital cataract, and microcornea syndrome). Transactivation was measured using luciferase reporter assays following cotransfection in HEK cells. Responsiveness to wildtype c-MAF was established for each of the four crystallin promoter constructs. The same constructs were then investigated using c-MAF mutants corresponding to each of the three mutations. A differential response was noted for each of the tested crystallin genes. The mutation R288P significantly reduced the expression of the CRYGA and CRYBA1 constructs but had no significant effect on the other two constructs. K297R did not lead to a significant reduction in expression of any of the four constructs, although there was a tendency toward reduced expression especially for the CRYGA construct. R299S, which is associated with the most severe phenotype, congenital cataract, and microcornea syndrome, was associated with the most severe overall effect on the transactivation of the four crystallin expression constructs. Our findings suggest that differential effects of mutations on the transactivation potential of c-MAF could be a molecular correlate of the striking genotype-phenotype correlations seen in cataract forms caused by mutations in the MAF gene.

Alpha beta-crystallin expression and presentation following infection with murine gammaherpesvirus 68.

Alpha beta-crystallin (CRYAB) is a small heat shock protein that can function as a molecular chaperone and has protective effects for cells undergoing a variety of stressors. Surprisingly, CRYAB has been identified as one of the dominant autoantigens in multiple sclerosis. It has been suggested that autoimmune mediated destruction of this small heat shock protein may limit its protective effects, thereby exacerbating inflammation and cellular damage during multiple sclerosis. It is not altogether clear how autoimmunity against CRYAB might develop, or whether there are environmental factors which might facilitate the presentation of this autoantigen to CD4+ T lymphocytes. In the present study, we utilized an animal model of an Epstein Barr Virus (EBV)-like infection, murine gammaherpesvirus 68 (HV-68), to question whether such a virus could modulate the expression of CRYAB by antigen presenting cells. Following exposure to HV-68 and several other stimuli, in vitro secretion of CRYAB and subsequent intracellular accumulation were observed in cultured macrophages and dendritic cells. Following infection of mice with this virus, it was possible to track CRYAB expression in the spleen and in antigen presenting cell subpopulations, as well as its secretion into the blood. Mice immunized with human CRYAB mounted a significant immune response against this heat shock protein. Further, dendritic cells that were exposed to HV-68 could stimulate CD4+ T cells from CRYAB immunized mice to secrete interferon gamma. Taken together these studies are consistent with the notion of a gammaherpesvirus-induced CRYAB response in professional antigen presenting cells in this mouse model.

Identification of a novel CRYBB2 missense mutation causing congenital autosomal dominant cataract.

PURPOSE: To identify the genetic defect in a four-generation Croatian family presenting with autosomal dominant cataract. METHODS: Genome-wide linkage analysis with 250K single nucleotide polymorphism (SNP) arrays was performed using DNA from one unaffected and seven affected individuals. Mutation screening of candidate genes was performed by bidirectional Sanger sequencing. RESULTS: Evidence for linkage was observed for eight genomic regions. Among these was a locus on chromosome 22 which encompasses the ß-crystallin gene cluster. This cluster includes four genes, namely beta-crystallin B1 (CRYBB1), beta-crystallin B2 (CRYBB2), beta-crystallin B3 (CRYBB3), and beta-crystallin A4 (CRYBA4). A novel sequence variant was found in the CRYBB2 gene (p.Arg188His). This variant cosegregated with the disease phenotype in all affected individuals but was not present in the unaffected family members and 100 healthy control subjects. CONCLUSIONS: We report a novel missense mutation, p.Arg188His, in CRYBB2 associated with congenital cataract in a family of Croatian origin. This variant is the most COOH-terminal missense mutation in CRYBB2 that has been identified so far.

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.

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.

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.

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.