Towards the Identification and Characterization of Putative Adult Human Lens Epithelial Stem Cells.

The anterior lens epithelium has the ability to differentiate into lens fibres throughout its life. The present study aims to identify and functionally characterize the adult stem cells in the human lens epithelium. Whole mounts of lens epithelium from donor eyes (normal/cataract) were immunostained for SOX2, gap junction protein alpha 1 (GJA1), PAX6, α, ß and γ-crystallins, followed by a confocal analysis. The functional property of adult stem cells was analysed by their sphere forming ability using cultured lens epithelial cells from different zones. Based on marker expression, the lens epithelium was divided into four zones: the central zone, characterized by a small population of PAX6+, GJA1-, ß-crystallin- and γ-crystallin- cells; the germinative zone, characterized by PAX6+, GJA1+, ß-crystallin- and γ-crystallin-; the transitional zone, characterized by PAX6+, GJA1+, ß-crystallin+ and γ-crystallin-; and the equatorial zone, characterized by PAX6+/-, GJA1+, ß-crystallin+, and γ-crystallin+ cells. The putative lens epithelial stem cells identified as SOX2+ and GJA1 membrane expression negative cells were located only in the central zone (1.89 ± 0.84%). Compared to the other zones, a significant percentage of spheres were identified in the central zone (1.68 ± 1.04%), consistent with the location of the putative adult lens epithelial stem cells. In the cataractous lens, an absence of SOX2 expression and a significant reduction in sphere forming ability (0.33 ± 0.11%) were observed in the central zone. The above findings confirmed the presence of putative stem cells in the central zone of the adult human lens epithelium and indicated their probable association with cataract development.

Binding of ßL-Crystallin with Models of Animal and Human Eye Lens-Lipid Membrane.

Several discoveries show that with age and cataract formation, ß-crystallin binds with the lens membrane or associates with other lens proteins, which bind with the fiber cell plasma membrane, accompanied by light scattering and cataract formation. However, how lipids (phospholipids and sphingolipids) and cholesterol (Chol) influence ß-crystallin binding to the membrane is unclear. This research aims to elucidate the role of lipids and Chol in the binding of ß-crystallin to the membrane and the membrane's physical properties (mobility, order, and hydrophobicity) with ß-crystallin binding. We used electron paramagnetic resonance (EPR) spin-labeling methods to investigate the binding of ßL-crystallin with a model of porcine lens-lipid (MPLL), model of mouse lens-lipid (MMLL), and model of human lens-lipid (MHLL) membrane with and without Chol. Our results show that ßL-crystallin binds with all of the investigated membranes in a saturation manner, and the maximum parentage of the membrane surface occupied (MMSO) by ßL-crystallin and the binding affinity (Ka) of ßL-crystallin to the membranes followed trends: MMSO (MPLL) > MMSO (MMLL) > MMSO (MHLL) and Ka (MHLL) > Ka (MMLL) ≈ Ka (MPLL), respectively, in which the presence of Chol reduces the MMSO and Ka for all membranes. The mobility near the headgroup regions of the membranes decreases with an increase in the binding of ßL-crystallin; however, the decrease is more pronounced in the MPLL and MMLL membranes than the MHLL membrane. In the MPLL and MMLL membranes, the membranes become slightly ordered near the headgroup with an increase in ßL-crystallin binding compared to the MHLL membrane. The hydrophobicity near the headgroup region of the membrane increases with ßL-crystallin binding; however, the increase is more pronounced in the MPLL and MMLL membranes than the MHLL membrane, indicating that ßL-crystallin binding creates a hydrophobic barrier for the passage of polar molecules, which supports the barrier hypothesis in cataract formation. However, in the presence of Chol, there is no significant increase in hydrophobicity with ßL-crystallin binding, suggesting that Chol prevents the formation of a hydrophobic barrier, possibly protecting against cataract formation.

Eye lens ß-crystallins are predicted by native ion mobility-mass spectrometry and computations to form compact higher-ordered heterooligomers.

Eye lens α- and ß-/γ-crystallin proteins are not replaced after fiber cell denucleation and maintain lens transparency and refractive properties. The exceptionally high (∼400-500 mg/mL) concentration of crystallins in mature lens tissue and multiple other factors impede precise characterization of ß-crystallin interactions, oligomer composition, size, and topology. Native ion mobility-mass spectrometry is used here to probe ß-crystallin association and provide insight into homo- and heterooligomerization kinetics for these proteins. These experiments include separation and characterization of higher-order ß-crystallin oligomers and illustrate the unique advantages of native IM-MS. Recombinantly expressed ßB1, ßB2, and ßA3 isoforms are found to have different homodimerization propensities, and only ßA3 forms larger homooligomers. Heterodimerization of ßB2 with ßA3 occurs ∼3 times as fast as that of ßB1 with ßA3, and ßB1 and ßB2 heterodimerize less readily. Ion mobility experiments, molecular dynamics simulations, and PISA analysis together reveal that observed oligomers are consistent with predominantly compact, ring-like topologies.

Conformational stability of the deamidated and mutated human ßB2-crystallin.

Previous studies propose that genetic mutations and post-translational modifications in protein crystallins promote protein aggregation and are considered significant risk factors for cataract formation. The ßB2-crystallin (HßB2C) forms a high proportion of proteins in the human eye lens. Different congenital mutations and post-translational deamidations in ßB2-crystallin have been reported and linked to cataract formation. In this work, we employed extensive all-atom molecular dynamics simulations to evaluate the conformational stability of deamidated and mutated HßB2C. Our results show critical changes in the protein surface and its native contacts due to a modification in the conformational equilibrium of these proteins. The double deamidated (Q70E/Q162E) and single deamidated (Q70E) impact the well compact conformation of the HßB2C. These post-translational modifications allow the exposure of the protein hydrophobic interface, which lead to the exposure of electronegative residues. On the other hand, our mutational studies showed that the S143F mutation modifies the hydrogen-bond network of an antiparallel ß-sheet, unfolding the C-terminal domain. Interestingly, the chain termination mutation (Q155X) does not unfold the N-terminal domain. However, the resultant conformation is more compact and avoids the exposure of the hydrophobic interface. Our results provide valuable information about the first steps of HßB2C unfolding in the presence of deamidated amino acids that have been reported to appear during aging. The findings reported in this work are essential for the general knowledge of the initial steps in the cataract formation mechanism, which may be helpful for the further development of molecules with pharmacological potential against cataract disease.

FGF-2 Differentially Regulates Lens Epithelial Cell Behaviour during TGF-ß-Induced EMT.

Fibroblast growth factor (FGF) and transforming growth factor-beta (TGF-ß) can regulate and/or dysregulate lens epithelial cell (LEC) behaviour, including proliferation, fibre differentiation, and epithelial-mesenchymal transition (EMT). Earlier studies have investigated the crosstalk between FGF and TGF-ß in dictating lens cell fate, that appears to be dose dependent. Here, we tested the hypothesis that a fibre-differentiating dose of FGF differentially regulates the behaviour of lens epithelial cells undergoing TGF-ß-induced EMT. Postnatal 21-day-old rat lens epithelial explants were treated with a fibre-differentiating dose of FGF-2 (200 ng/mL) and/or TGF-ß2 (50 pg/mL) over a 7-day culture period. We compared central LECs (CLECs) and peripheral LECs (PLECs) using immunolabelling for changes in markers for EMT (α-SMA), lens fibre differentiation (ß-crystallin), epithelial cell adhesion (ß-catenin), and the cytoskeleton (alpha-tropomyosin), as well as Smad2/3- and MAPK/ERK1/2-signalling. Lens epithelial explants cotreated with FGF-2 and TGF-ß2 exhibited a differential response, with CLECs undergoing EMT while PLECs favoured more of a lens fibre differentiation response, compared to the TGF-ß-only-treated explants where all cells in the explants underwent EMT. The CLECs cotreated with FGF and TGF-ß immunolabelled for α-SMA, with minimal ß-crystallin, whereas the PLECs demonstrated strong ß-crystallin reactivity and little α-SMA. Interestingly, compared to the TGF-ß-only-treated explants, α-SMA was significantly decreased in the CLECs cotreated with FGF/TGF-ß. Smad-dependent and independent signalling was increased in the FGF-2/TGF-ß2 co-treated CLECs, that had a heightened number of cells with nuclear localisation of Smad2/3 compared to the PLECs, that in contrast had more pronounced ERK1/2-signalling over Smad2/3 activation. The current study has confirmed that FGF-2 is influential in differentially regulating the behaviour of LECs during TGF-ß-induced EMT, leading to a heterogenous cell population, typical of that observed in the development of post-surgical, posterior capsular opacification (PCO). This highlights the cooperative relationship between FGF and TGF-ß leading to lens pathology, providing a different perspective when considering preventative measures for controlling PCO.

Manipulating polydispersity of lens ß-crystallins using divalent cations demonstrates evidence of calcium regulation.

Crystallins comprise the protein-rich tissue of the eye lens. Of the three most common vertebrate subtypes, ß-crystallins exhibit the widest degree of polydispersity due to their complex multimerization properties in situ. While polydispersity enables precise packing densities across the concentration gradient of the lens for vision, it is unclear why there is such a high degree of structural complexity within the ß-crystallin subtype and what the role of this feature is in the lens. To investigate this, we first characterized ß-crystallin polydispersity and then established a method to dynamically disrupt it in a process that is dependent on isoform composition and the presence of divalent cationic salts (CaCl2 or MgCl2). We used size-exclusion chromatography together with dynamic light scattering and mass spectrometry to show how high concentrations of divalent cations dissociate ß-crystallin oligomers, reduce polydispersity, and shift the overall protein surface charge-properties that can be reversed when salts are removed. While the direct, physiological relevance of these divalent cations in the lens is still under investigation, our results support that specific isoforms of ß-crystallin modulate polydispersity through multiple chemical equilibria and that this native state is disrupted by cation binding. This dynamic process may be essential to facilitating the molecular packing and optical function of the lens.

Zinc and Copper Ions Induce Aggregation of Human ß-Crystallins.

Cataracts are defined as the clouding of the lens due to the formation of insoluble protein aggregates. Metal ions exposure has been recognized as a risk factor in the cataract formation process. The γ and ß crystallins are members of a larger family and share several structural features. Several studies have shown that copper and zinc ions induce the formation of γ-crystallins aggregates. However, the interaction of metal ions with ß-crystallins, some of the most abundant crystallins in the lens, has not been explored until now. Here, we evaluate the effect of Cu(II) and Zn(II) ions on the aggregation of HßA1, as a representative of the acidic form, and HßB2, as a representative of the basic ß-crystallins. We used several biophysical techniques and computational methods to show that Cu(II) and Zn(II) induce aggregation following different pathways. Both metal ions destabilize the proteins and impact protein folding. Copper induced a small conformational change in HßA1, leading to high-molecular-weight light-scattering aggregates, while zinc is more aggressive towards HßB2 and induces a larger conformational change. Our work provides information on the mechanisms of metal-induced aggregation of ß-crystallins.

Aberrant TGF-ß1 signaling activation by MAF underlies pathological lens growth in high myopia.

High myopia is a leading cause of blindness worldwide. Myopia progression may lead to pathological changes of lens and affect the outcome of lens surgery, but the underlying mechanism remains unclear. Here, we find an increased lens size in highly myopic eyes associated with up-regulation of ß/γ-crystallin expressions. Similar findings are replicated in two independent mouse models of high myopia. Mechanistic studies show that the transcription factor MAF plays an essential role in up-regulating ß/γ-crystallins in high myopia, by direct activation of the crystallin gene promoters and by activation of TGF-ß1-Smad signaling. Our results establish lens morphological and molecular changes as a characteristic feature of high myopia, and point to the dysregulation of the MAF-TGF-ß1-crystallin axis as an underlying mechanism, providing an insight for therapeutic interventions.

Identification and characterization of six ß-crystallin gene mutations associated with congenital cataract in Chinese families.

BACKGROUND: This study aims to identify the underlying genetic defects of ß-crystallin (CRYB) genes responsible for congenital cataracts in a group of Chinese families. METHODS: Detailed family history and clinical data of six Chinese families with autosomal dominant congenital cataracts were recorded. Targeted exome sequencing was applied to detect the underlying genetic defects for the families. Generated variants were confirmed by PCR and sanger sequencing. Afterward, bioinformatic analysis through several computational predictive programs was performed to assess impacts of mutations on protein structure and function. RESULTS: A total of 53 participants (23 affected and 30 unaffected) from six unrelated Chinese families were recruited. Cataract phenotypes covered nuclear, total, posterior polar, pulverulent, snowflake-like, and zonular. Through targeted exome sequencing, six mutations in four ß-crystallin genes were revealed which included five missense mutations CRYBB1 p.Q70P, CRYBB2 p.E23Q, CRYBB2 p.A49V, CRYBB2 R188C, CRYBA4 p.M14K and one splice mutation CRYBB3 c.75+1 G>A. In silico results predicted pathogenic for all four missense variants except variant CRYBB2-p.A49V yielded results as tolerant. The CRYBB3 c.75+1 G>A splice site mutation was predicted to be deleterious by leading to a broken splice site, a premature stop codon, and subsequently resulting in a short peptide of 113 amino acids, which may affect protein features. CONCLUSION: The obtained results expanded mutational and phenotype spectrum of ß-crystallin genes and offer clues for pathogenesis of congenital cataracts. The data also demonstrated that targeted exome sequencing is valuable for providing molecular diagnostic information for congenital cataract patients.

Crowding in the Eye Lens: Modeling the Multisubunit Protein ß-Crystallin with a Colloidal Approach.

We present a multiscale characterization of aqueous solutions of the bovine eye lens protein ßH crystallin from dilute conditions up to dynamical arrest, combining dynamic light scattering, small-angle x-ray scattering, tracer-based microrheology, and neutron spin echo spectroscopy. We obtain a comprehensive explanation of the observed experimental signatures from a model of polydisperse hard spheres with additional weak attraction. In particular, the model predictions quantitatively describe the multiscale dynamical results from microscopic nanometer cage diffusion over mesoscopic micrometer gradient diffusion up to macroscopic viscosity. Based on a comparative discussion with results from other crystallin proteins, we suggest an interesting common pathway for dynamical arrest in all crystallin proteins, with potential implications for the understanding of crowding effects in the eye lens.

Eye lens crystallin proteins inhibit the autocatalytic amyloid amplification nature of mature α-synuclein fibrils.

Parkinson´s disease is characterized by the accumulation of proteinaceous aggregates in Lewy bodies and Lewy Neurites. The main component found in such aggregates is α-synuclein. Here, we investigate how bovine eye lens crystallin proteins influence the aggregation kinetics of α-synuclein at mildly acidic pH (5.5) where the underlying aggregation mechanism of this protein is dominated by secondary nucleation of monomers on fibril surface providing an autocatalytic amyloid amplification process. Bovine α-, ßH- and γB-crystallins were found to display chaperone-like activity inhibiting α-synuclein aggregation. This effect was shown to be time-dependent, with early additions of α-crystallin capable of retarding and even inhibiting aggregation during the time frame of the experiment. The inhibitory nature of crystallins was further investigated using trap and seed kinetic experiments. We propose crystallins interact with mature α-synuclein fibrils, possibly binding along the surfaces and at fibril free ends, inhibiting both elongation and monomer-dependent secondary nucleation processes in a mechanism that may be generic to some chaperones that prevent the onset of protein misfolding related pathologies.

PNU282987 inhibits amyloid­ß aggregation by upregulating astrocytic endogenous αB­crystallin and HSP­70 via regulation of the α7AChR, PI3K/Akt/HSF­1 signaling axis.

Alzheimer's disease (AD) is a chronic and irreversible neurodegenerative disorder. Abnormal aggregation of the neurotoxic amyloid­ß (Aß) peptide is an early event in AD. The activation of astrocytic α7 nicotinic acetylcholine receptor (α7 nAChR) can inhibit Aß aggregation; thus, the molecular mechanism between α7 nAChR activation and Aß aggregation warrants further investigation. In the present study, Aß oligomer levels were assessed in astrocytic cell lysates after treatment with PNU282987 (a potent agonist of α7 nAChRs) or co­treatment with LY294002, a p­Akt inhibitor. The levels of heat shock factor­1 (HSF­1), heat shock protein 70 (HSP­70), and αB­crystallin (Cryab) in astrocytes treated with PNU282987 at various time­points or co­treated with methyllycaconitine (MLA), a selective α7 nAChR antagonist, as well as co­incubated with LY294002 were determined by western blotting. HSP­70 and Cryab levels were determined after HSF­1 knockdown (KD) in astrocytes. PNU282987 markedly inhibited Aß aggregation and upregulated HSF­1, Cryab, and HSP­70 in primary astrocytes, while the PNU282987­mediated neuroprotective effect was reversed by pre­treatment with MLA or LY294002. Moreover, the HSF­1 KD in astrocytes effectively decreased Cryab, but not HSP­70 expression. HSF­1 is necessary for the upregulation of Cryab expression, but not for that of HSP­70. HSF­1 and HSP­70 have a neuroprotective effect. Furthermore, the neuroprotective effect of PNU282987 against Aß aggregation was mediated by the canonical PI3K/Akt signaling pathway activation.

Aggregation of ß-crystallin through covalent binding to 1,2-naphthoquinone is rescued by α-crystallin chaperone.

Cataract induced by exposure to naphthalene is thought to mainly involve its metabolic activation, forming 1,2-naphthoquinone (1,2-NQ), which can modify proteins through chemical modifications. In the present study, we examined the effect of 1,2-NQ on aggregation of crystallins (cry) associated with cataract. Incubation of bovine ß-cry with 1,2-NQ caused covalent modification of ß-cry at Cys117 and Lys125 accompanied by reduction in its thiol content, resulting in a concentration- and temperature-dependent aggregation of ß-cry, whereas only little aggregation of α-cry induced by 1,2-NQ was seen. Interestingly, addition of α-cry to the reaction mixture of ß-cry and 1,2-NQ markedly blocked ß-cry aggregation induced by 1,2-NQ in a concentration-dependent manner. These results suggest that ß-cry predominantly undergoes chemical modification by 1,2-NQ, causing its aggregation, which is suppressed by the chaperone-like protein, α-cry. This ß-cry aggregation may be, at least in part, involved in the induction of cataract caused by 1,2-NQ.

MALDI imaging mass spectrometry of ß- and γ-crystallins in the ocular lens.

Lens crystallin proteins make up 90% of expressed proteins in the ocular lens and are primarily responsible for maintaining lens transparency and establishing the gradient of refractive index necessary for proper focusing of images onto the retina. Age-related modifications to lens crystallins have been linked to insolubilization and cataractogenesis in human lenses. Matrix-assisted laser desorption/ionization (MALDI) imaging mass spectrometry (IMS) has been shown to provide spatial maps of such age-related modifications. Previous work demonstrated that, under standard protein IMS conditions, α-crystallin signals dominated the mass spectrum and age-related modifications to α-crystallins could be mapped. In the current study, a new sample preparation method was optimized to allow imaging of ß- and γ-crystallins in ocular lens tissue. Acquired images showed that γ-crystallins were localized predominately in the lens nucleus whereas ß-crystallins were primarily localized to the lens cortex. Age-related modifications such as truncation, acetylation, and carbamylation were identified and spatially mapped. Protein identifications were determined by top-down proteomics analysis of lens proteins extracted from tissue sections and analyzed by LC-MS/MS with electron transfer dissociation. This new sample preparation method combined with the standard method allows the major lens crystallins to be mapped by MALDI IMS.

Divalent Cations and the Divergence of ßγ-Crystallin Function.

The ßγ-crystallin superfamily contains both ß- and γ-crystallins of the vertebrate eye lens and the microbial calcium-binding proteins, all of which are characterized by a common double-Greek key domain structure. The vertebrate ßγ-crystallins are long-lived structural proteins that refract light onto the retina. In contrast, the microbial ßγ-crystallins bind calcium ions. The ßγ-crystallin from the tunicate Ciona intestinalis (Ci-ßγ) provides a potential link between these two functions. It binds calcium with high affinity and is found in a light-sensitive sensory organ that is highly enriched in metal ions. Thus, Ci-ßγ is valuable for investigating the evolution of the ßγ-crystallin fold away from calcium binding and toward stability in the apo form as part of the vertebrate lens. Here, we investigate the effect of Ca2+ and other divalent cations on the stability and aggregation propensity of Ci-ßγ and human γS-crystallin (HγS). Beyond Ca2+, Ci-ßγ is capable of coordinating Mg2+, Sr2+, Co2+, Mn2+, Ni2+, and Zn2+, although only Sr2+ is bound with comparable affinity to its preferred metal ion. The extent to which the tested divalent cations stabilize Ci-ßγ structure correlates strongly with ionic radius. In contrast, none of the tested divalent cations improved the stability of HγS, and some of them induced aggregation. Zn2+, Ni2+, and Co2+ induce aggregation by interacting with cysteine residues, whereas Cu2+-mediated aggregation proceeds via a different binding site.

ßγ-Crystallination Endows a Novel Bacterial Glycoside Hydrolase 64 with Ca2+-Dependent Activity Modulation.

The prokaryotic ßγ-crystallins are a large group of uncharacterized domains with Ca2+-binding motifs. We have observed that a vast number of these domains are found appended to other domains, in particular, the carbohydrate-active enzyme (CAZy) domains. To elucidate the functional significance of these prospective Ca2+ sensors in bacteria and this widespread domain association, we have studied one typical example from Clostridium beijerinckii, a bacterium known for its ability to produce acetone, butanol, and ethanol through fermentation of several carbohydrates. This novel glycoside hydrolase of family 64 (GH64), which we named glucanallin, is composed of a ßγ-crystallin domain, a GH64 domain, and a carbohydrate-binding module 56 (CBM56). The substrates of GH64, ß-1,3-glucans, are the targets for industrial biofuel production due to their plenitude. We have examined the Ca2+-binding properties of this protein, assayed its enzymatic activity, and analyzed the structural features of the ß-1,3-glucanase domain through its high-resolution crystal structure. The reaction products resulting from the enzyme reaction of glucanallin reinforce the mixed nature of GH64 enzymes, in contrast to the prevailing notion of them being an exotype. Upon disabling Ca2+ binding and comparing different domain combinations, we demonstrate that the ßγ-crystallin domain in glucanallin acts as a Ca2+ sensor and enhances the glycolytic activity of glucanallin through Ca2+ binding. We also compare the structural peculiarities of this new member of the GH64 family to two previously studied members.IMPORTANCE We have biochemically and structurally characterized a novel glucanase from the less studied GH64 family in a bacterium significant for fermentation of carbohydrates into biofuels. This enzyme displays a peculiar property of being distally modulated by Ca2+ via assistance from a neighboring ßγ-crystallin domain, likely through changes in the domain interface. In addition, this enzyme is found to be optimized for functioning in an acidic environment, which is in line with the possibility of its involvement in biofuel production. Multiple occurrences of a similar domain architecture suggest that such a "ßγ-crystallination"-mediated Ca2+ sensitivity may be widespread among bacterial proteins.

The mechanism of the interaction of α-crystallin and UV-damaged ßL-crystallin.

α-Crystallin maintains the transparency of the lens by preventing the aggregation of damaged proteins. The aim of our work was to study the chaperone-like activity of native α-crystallin in near physiological conditions (temperature, ionic power, pH) using UV-damaged ßL-crystallin as the target protein. α-Crystallin in concentration depended manner inhibits the aggregation of UV-damaged ßL-crystallin. DSC investigation has shown that refolding of denatured UV-damaged ßL-crystallin was not observed under incubation with α-crystallin. α-Crystallin and UV-damaged ßL-crystallin form dynamic complexes with masses from 75 to several thousand kDa. The content of UV-damaged ßL-crystallin in such complexes increases with the mass of the complex. Complexes containing >10% of UV-damaged ßL-crystallin are prone to precipitation whereas those containing <10% of the target protein are relatively stable. Formation of a stable 75 kDa complex is indicative of α-crystallin dissociation. We suppose that α-crystallin dissociation is the result of an interaction of comparable amounts of the chaperone-like protein and the target protein. In the lens simultaneous damage of such amounts of protein, mainly ß and gamma-crystallins, is impossible. The authors suggest that in the lens rare molecules of the damaged protein interact with undissociated oligomers of α-crystallin, and thus preventing aggregation.

Biochemical characterization of G64W mutant of acidic beta-crystallin 4.

Crystallins are structural proteins in the lens that last a lifetime with little turnover. Deviant in crystallins can cause rare but severe visual impairment, namely, congenital cataracts. It is reported that several mutations in the acidic ß-crystallin 4 (CRYBA4) are related to congenital cataracts. However, the pathogenesis of these mutants is not well understood at molecular level. Here we evaluate the biochemical properties of wild type CRYBA4 (CRYBA4WT) and a pathogenic G64W mutant (CRYBA4G64W) including protein folding, polymerization state and protein stability. Furthermore, we explore the differences in their interactions with α-crystallin A (CRYAA) and basic ß-crystallin 1 (CRYBB1) via yeast two-hybrid and pull-down assay in vitro, through which we find that G64W mutation leads to protein misfolding, decreases protein stability, blocks its interaction with CRYBB1 but maintains its interaction with CRYAA. Our results deepen our understanding of the pathogenesis of congenital cataracts.

Dissimilarity in the Contributions of the N-Terminal Domain Hydrophobic Core to the Structural Stability of Lens ß/γ-Crystallins.

Vertebrate lens ß/γ-crystallins share a conserved tertiary structure consisting of four Greek-key motifs divided into two globular domains. Numerous inherited mutations in ß/γ-crystallins have been linked to cataractogenesis. In this research, the folding mechanism underlying cataracts caused by the I21N mutation in ßB2 was investigated by comparing the effect of mutagenesis on the structural features and stability of four ß/γ-crystallins, ßB1, ßB2, γC, and γD. Our results showed that the four ß/γ-crystallins differ greatly in solubility and stability against various stresses. The I21N mutation greatly impaired ßB2 solubility and native structure as well as its stability against denaturation induced by guanidine hydrochloride, heat treatment, and ultraviolet irradiation. However, the deleterious effects were much weaker for mutations at the corresponding sites in ßB1, γC, and γD. Molecular dynamics simulations indicated that the introduction of a nonnative hydrogen bond contributed to twisting Greek-key motif I outward, which might direct the misfolding of the I21N mutant of ßB2. Meanwhile, partial hydration of the hydrophobic interior of the domain induced by the mutation destabilized ßB1, γC, and γD. Our findings highlight the importance of nonnative hydrogen bond formation and hydrophobic core hydration in crystallin misfolding caused by inherited mutations.

Polyphenol-enriched fraction of Vaccinium uliginosum L. protects selenite-induced cataract formation in the lens of Sprague-Dawley rat pups.

Purpose: As the aging population is increasing, the incidence of age-related cataract is expected to increase globally. The surgical intervention, a treatment for cataract, still has complications and is limited to developed countries. In this study, we investigated whether the polyphenol-enriched fraction of Vaccinium uliginosum L. (FH) prevents cataract formation in Sprague-Dawley (SD) rat pups. Methods: Sixty rat pups were randomly divided into six groups: CTL, Se, FH40, FH80, FH120, and Cur80. The cataract was induced with subcutaneous injection of sodium selenite (18 µmol/kg bodyweight) on postnatal (P) day 10. All groups, except CTL, were injected with sodium selenite, and the FH40, FH80, and FH120 groups were given gastric intubation with FH40 mg/kg, 80 mg/kg, and 120 mg/kg on P9, P10, and P11. The Cur80 group was also given gastric intubation with curcumin 80 mg/kg on P9, P10, and P11. All rat pups were euthanized on P30. Results: Lens morphological analysis showed that FH dose-dependently inhibited cataract formation. In the Se group, soluble proteins were insolubilized, and the gene expression of the α-, ß-, and γ-crystallins was downregulated. However, FH treatment statistically significantly inhibited insolubilization of soluble proteins and downregulation of the gene expression of the α-, ß-, and γ-crystallins. In the Se group, the gene and protein levels of m-calpain were downregulated, which were attenuated with FH treatment. In addition, sodium selenite injection caused reduced antioxidant enzymes (superoxide dismutase (SOD) and glutathione peroxidase (GPx)), glutathione (GSH) depletion, and malondialdehyde (MDA) production in the lens. The administration of FH inhibited sodium selenite-induced oxidative stress in a dose-dependent manner. The mechanism of protection against oxidative stress by FH involves NF-E2-related factor (Nrf-2) and hemoxygenase-1 (HO-1). FH treatment inhibited decrease of Nrf-2 in the nucleus fraction and HO-1 in the cytosol fraction. Finally, the FH treatment protected poly (ADP)-ribose polymerase (PARP) from cleavage, determined with western blotting. Conclusions: FH showed a preventive effect against cataract formation by inhibiting m-calpain-mediated proteolysis and oxidative stress in the lens. These results suggest that FH could be a potential anticataract agent in age-related cataract.