Partially Folded Aggregation Intermediates of Human γD-, γC-, and γS-Crystallin Are Recognized and Bound by Human αB-Crystallin Chaperone

Human γ-crystallins are long-lived, unusually stable proteins of the eye lens exhibiting duplicated, double Greek key domains. The lens also contains high concentrations of the small heat shock chaperone α-crystallin, which suppresses aggregation of model substrates in vitro. Mature-onset cataract is believed to represent an aggregated state of partially unfolded and covalently damaged crystallins. Nonetheless, the lack of cell or tissue culture for anucleate lens fibers and the insoluble state of cataract proteins have made it difficult to identify the conformation of the human γ-crystallin substrate species recognized by human α-crystallin. The three major human lens monomeric γ-crystallins, γD, γC, and γS, all refold in vitro in the absence of chaperones, on dilution from denaturant into buffer. However, off-pathway aggregation of the partially folded intermediates competes with productive refolding. Incubation with human αB-crystallin chaperone during refolding suppressed the aggregation pathways of the three human γ-crystallin proteins. The chaperone did not dissociate or refold the aggregated chains under these conditions. The αB-crystallin oligomers formed long-lived stable complexes with their γD-crystallin substrates. Using α-crystallin chaperone variants lacking tryptophans, we obtained fluorescence spectra of the chaperone-substrate complex. Binding of substrate γ-crystallins with two or three of the four buried tryptophans replaced by phenylalanines showed that the bound substrate remained in a partially folded state with neither domain native-like. These in vitro results provide support for protein unfolding/protein aggregation models for cataract, with α-crystallin suppressing aggregation of damaged or unfolded proteins through early adulthood but becoming saturated with advancing age.     

Methionine sulfoxide reductase A (MsrA) restores α-crystallin chaperone activity lost upon methionine oxidation

Background

Lens cataract is associated with protein oxidation and aggregation. Two proteins that cause cataract when deleted from the lens are methionine sulfoxide reductase A (MsrA) that repairs protein methionine sulfoxide (PMSO) oxidized proteins and α-crystallin which is a two-subunit (αA and αB) chaperone. Here, we tested whether PMSO formation damages α-crystallin chaperone function and whether MsrA could repair PMSO-α-crystallin.

Methods

Total α-crystallin was oxidized to PMSO and evaluated by CNBr-cleavage and mass spectrometry. Chaperone activity was measured by light scattering using lysozyme as target. PMSO-α-crystallin was treated with MsrA, and repair was assessed by CNBr cleavage, mass spectrometry and recovery of chaperone function. The levels of α-crystallin-PMSO in the lenses of MsrA-knockout relative to wild-type mice were determined.

Results

PMSO oxidation of total α-crystallin (met 138 of αA and met 68 of αB) resulted in loss of α-crystallin chaperone activity. MsrA treatment of PMSO-α-crystallin repaired its chaperone activity through reduction of PMSO. Deletion of MsrA in mice resulted in increased levels of PMSO-α-crystallin.

Conclusions

Methionine oxidation damages α-crystallin chaperone function and MsrA can repair PMSO-α-crystallin restoring its chaperone function. MsrA is required for maintaining the reduced state of α-crystallin methionines in the lens.

Significance

Methionine oxidation of α-crystallin in combination with loss of MsrA repair causes loss of α-crystallin chaperone function. Since increased PMSO levels and loss of α-crystallin function are hallmarks of cataract, these results provide insight into the mechanisms of cataract development and likely those of other age-related diseases.     

Effect of Trifluoroethanol on the Structural and Functional Properties of α-Crystallin

Alpha crystallin is an eye lens protein with a molecular weight of approximately 800 kDa. It belongs to the class of small heat shock proteins. Besides its structural role, it is known to prevent the aggregation of β- and γ-crystallins and several other proteins under denaturing conditions and is thus believed to play an important role in maintaining lens transparency. In this communication, we have investigated the effect of 2,2,2-trifluoroethanol (TFE) on the structural and functional features of the native α-crystallin and its two constituent subunits. A conformational change occurs from the characteristic β-sheet to the α-helix structure in both native α-crystallin and its subunits with the increase in TFE levels. Among the two subunits, αA-crystallin is relatively stable and upon preincubation prevents the characteristic aggregation of αB-crystallin at 20% and 30% (v/v) TFE. The hydrophobicity and chaperone-like activity of the crystallin subunits decrease on TFE treatment. The ability of αA-crystallin to bind and prevent the aggregation of αB-crystallin, despite a conformational change, could be important in protecting the lens from external stress. The loss in chaperone activity of αA-crystallin exposed to TFE and the inability of peptide chaperone—the functional site of αA-crystallin—to stabilize αB-crystallin at 20–30% TFE suggest that the site(s) involved in subunit interaction and chaperone-like function are quite distinct.     

αA-Crystallin Peptide 66 SDRDKFVIFLDVKHF 80 Accumulating in Aging Lens Impairs the Function of α-Crystallin and Induces Lens Protein Aggregation

Background

The eye lens is composed of fiber cells that are filled with α-, β- and γ-crystallins. The primary function of crystallins is to maintain the clarity of the lens through ordered interactions as well as through the chaperone-like function of α-crystallin. With aging, the chaperone function of α-crystallin decreases, with the concomitant accumulation of water-insoluble, light-scattering oligomers and crystallin-derived peptides. The role of crystallin-derived peptides in age-related lens protein aggregation and insolubilization is not understood.

Methodology/Principal Findings

We found that αA-crystallin-derived peptide, ⁶⁶ SDRDKFVIFLDVKHF ⁸⁰, which accumulates in the aging lens, can inhibit the chaperone activity of α-crystallin and cause aggregation and precipitation of lens crystallins. Age-related change in the concentration of αA-(66-80) peptide was estimated by mass spectrometry. The interaction of the peptide with native crystallin was studied by multi-angle light scattering and fluorescence methods. High molar ratios of peptide-to-crystallin were favourable for aggregation and precipitation. Time-lapse recordings showed that, in the presence of αA-(66-80) peptide, α-crystallin aggregates and functions as a nucleus for protein aggregation, attracting aggregation of additional α-, β- and γ-crystallins. Additionally, the αA-(66-80) peptide shares the principal properties of amyloid peptides, such as β-sheet structure and fibril formation.

Conclusions/Significance

These results suggest that crystallin-derived peptides such as αA-(66-80), generated in vivo, can induce age-related lens changes by disrupting the structure and organization of crystallins, leading to their insolubilization. The accumulation of such peptides in aging lenses may explain a novel mechanism for age-related crystallin aggregation and cataractogenesis.     

α-Crystallin Acting as a Molecular Chaperonin Against Photodamage by UV Irradiation

α-Crystallin, a major protein of the eye lens, is known to have chaperone activity in preventing heat-induced aggregation of enzymes and other crystallins. In this study, we investigate the ability of α-crystallin to inhibit UV-light-induced aggregation of other lens proteins and the effect of exposure of α-crystallin to UV irradiation on its chaperone activity. The chaperone activities of α-crystallin preincubated at different temperatures were found to be different and could be correlated with its change in quaternary structure as determined by the fluorescence probe ANS (8-anilo-1-naphthalene sulfonate). α-Crystallin can inhibit the aggregation of γ-crystallin from UV irradiation at room temperature, and the preheated α-crystallins provide more protection than the native one. Upon irradiation by UV light, α-crystallin gradually lost its ability to protect β-crystallin against thermal aggregation. The loss of the chaperone efficacy of α-crystallin to protect other lens proteins may shed light on human cataract formation induced by long-term exposure to UV irradiation.     

Aggregation of crystallins induced by pulsed laser UV light (308 nm)

Here we compile and analyze the data on photoaggregation of a model protein carboanhydrase and the main eye lens proteins α-, β-, γ-crystallins under the action of pulsed UV irradiation from a Xe-Cl laser (308 nm) with broad variation of pulse energy density and repetition rate. The aggregation efficacy proves to be a nonlinear function of these parameters and protein concentration. A theoretical model is proposed that qualitatively explains the experimental data. It is shown that N-arm-truncated βA3-crystallin is more prone to UV-induced aggregation than the full-sized protein; such defects caused by mutation or aging may aggravate the development of lenticular opacity. Analyzed is the effect of some low-molecular compounds on the aggregation of β-crystallin and its mixture with α-crystallin. A combination of short peptides prepared on this basis markedly impedes crystallin aggregation and retards the development of UV-induced cataract in rats.     

Association of partially folded lens betaB2-crystallins with the alpha-crystallin molecular chaperone

Age-related cataract is a result of crystallins, the predominant lens proteins, forming light-scattering aggregates. In the low protein turnover environment of the eye lens, the crystallins are susceptible to modifications that can reduce stability, increasing the probability of unfolding and aggregation events occurring. It is hypothesized that the alpha-crystallin molecular chaperone system recognizes and binds these proteins before they can form the light-scattering centres that result in cataract, thus maintaining the long-term transparency of the lens. In the present study, we investigated the unfolding and aggregation of (wild-type) human and calf betaB2-crystallins and the formation of a complex between alpha-crystallin and betaB2-crystallins under destabilizing conditions. Human and calf betaB2-crystallin unfold through a structurally similar pathway, but the increased stability of the C-terminal domain of human betaB2-crystallin relative to calf betaB2-crystallin results in the increased population of a partially folded intermediate during unfolding. This intermediate is aggregation-prone and prevents constructive refolding of human betaB2-crystallin, while calf betaB2-crystallin can refold with high efficiency. alpha-Crystallin can effectively chaperone both human and calf betaB2-crystallins from thermal aggregation, although chaperone-bound betaB2-crystallins are unable to refold once returned to native conditions. Ordered secondary structure is seen to increase in alpha-crystallin with elevated temperatures up to 60 degrees C; structure is rapidly lost at temperatures of 70 degrees C and above. Our experimental results combined with previously reported observations of alpha-crystallin quaternary structure have led us to propose a structural model of how activated alpha-crystallin chaperones unfolded betaB2-crystallin.     

Cataract-linked γD-crystallin mutants have weak affinity to lens chaperones α-crystallins

To test the hypothesis that α-crystallin chaperone activity plays a central role in maintenance of lens transparency, we investigated its interactions with γ-crystallin mutants that cause congenital cataract in mouse models. Although the two substitutions, I4F and V76D, stabilize a partially unfolded γD-crystallin intermediate, their affinities to α-crystallin are marginal even at relatively high concentrations. Detectable binding required further reduction of γD-crystallin stability which was achieved by combining the two mutations. Our results demonstrate that mutants and possibly age-damaged γ-crystallin can escape quality control by lens chaperones rationalizing the observation that they nucleate protein aggregation and lead to cataract.     

Effect of chronic hyperglycemia on crystallin levels in rat lens

Crystallins are the major structural proteins in the vertebrate eye lens that contribute to lens transparency. Although cataract, including diabetic cataract, is thought to be a result of the accumulation of crystallins with various modifications, the effect of hyperglycemia on status of crystallin levels has not been investigated. This study evaluated the effect of chronic hyperglycemia on crystallin levels in diabetic cataractous rat lens. Diabetes was induced in rats by injecting streptozotocin and maintained on hyperglycemia for a period of 10 weeks. At the end, levels of α-, β-, γ-crystallins and phosphoforms of αB-crystallins (αBC) were analyzed by immunoblotting. Further, solubility of crystallins and phosphoforms of αBC was analyzed by detergent soluble assay. Chronic diabetes significantly decreased the protein levels of α-, β- and αA-crystallins (αAC) in both soluble and insoluble fraction of lens. Whereas γ-crystallin levels were decreased and αBC levels were increased in lens soluble fraction with no change in insoluble fraction in diabetic rat lens. Although, diabetes activated the p38MAPK signaling cascade by increasing the p-p38MAPK in lens, the phosphoforms of αBC were decreased in soluble fraction with a concomitant increase in insoluble fraction of diabetic lens when compared to the controls. Moreover, diabetes strongly enhances the degradation of crystallins and phosphoforms of αBC in lens. Taken together, the decreased levels of crystallins and insolubilization of phosphoforms of αBC under chronic hyperglycemia could be one of the underlying factors in the development of diabetic cataract.     

Ontogeny and localization of the α, β, and γ crystallins in newt eye lens development

The α-, β-, and γ-crystallins, proteins characteristic for the vertebrate eye lens, have been localized in the developing lens of Notophthalmus viridescens, the eastern spotted newt. Using the immunofluorescence technique, antibodies to the α-, β-, and γ-crystallin classes were applied to tissue sections through the eye region of developing N. viridescens embryos, Harrison (external) Stages 30 to 46+. β-Crystallins were the first of the crystallins to appear in a few cells of the lens vesicle even before the lengthening of the prospective primary fiber cells. γ-Crystallins were first detectable at a slightly more advanced stage in the prospective primary fibers, and α-crystallins in a few cells of the beginning primary fiber area. The external layer/epithelium was negative for β-crystallins until late in lens morphogenesis, and α- and γ-crystallins could not be detected in these cells at any time. This, the first use in amphibia of homologous antibodies specific for the crystallin classes, makes clear that phylogenetic differences exist as to the primacy and relevance of specific crystallins to events during morphogenesis of the eye lens.     

The human crystallin gene families

Crystallins are the abundant, long-lived proteins of the eye lens. The major human crystallins belong to two different superfamilies: the small heat-shock proteins (α-crystallins) and the βγ-crystallins. During evolution, other proteins have sometimes been recruited as crystallins to modify the properties of the lens. In the developing human lens, the enzyme betaine-homocysteine methyltransferase serves such a role. Evolutionary modification has also resulted in loss of expression of some human crystallin genes or of specific splice forms. Crystallin organization is essential for lens transparency and mutations; even minor changes to surface residues can cause cataract and loss of vision.     

Mutations of small heat shock proteins and human congenital diseases

The structure and properties of different members of a large family of small heat shock proteins (sHsp) playing an important role in cell homeostasis are described. Participation of the N-terminal domain in formation of large oligomers and chaperone activity of sHsp is analyzed. The structure of the α-crystallin domain of sHsp is characterized and the role of this domain in sHsp dimerization and chaperone activity is discussed. The properties of the C-terminal region of sHsp are described, and its participation in formation of large oligomers and chaperone activity are analyzed. The data from the literature on HspB1 and HspB3 mutations are presented, and involvement of these mutations in development of certain neurodegenerative diseases is discussed. Mutations of HspB4 are described and data on involvement of these mutations in development of cataract are presented. Multiple effects of HspB5 mutations are analyzed, and data are presented indicating that mutations of this protein are accompanied by development of different congenital diseases, such as cataract and different types of myopathies. The data on HspB6 and HspB8 mutations are presented, and feasible effects of these mutations on proteins structure are analyzed. Probable mechanisms underlying sHsp mutation-induced development of different congenital diseases are discussed.     

Alpha-crystallin-mediated protection of lens cells against heat and oxidative stress-induced cell death

In addition to their key role as structural lens proteins, α-crystallins also appear to confer protection against many eye diseases, including cataract, retinitis pigmentosa, and macular degeneration. Exogenous recombinant α-crystallin proteins were examined for their ability to prevent cell death induced by heat or oxidative stress in a human lens epithelial cell line (HLE-B3). Wild type αA- or αB-crystallin (WT-αA and WT-αB) and αA- or αB-crystallins, modified by the addition of a cell penetration peptide (CPP) designed to enhance the uptake of proteins into cells (gC-αB, TAT-αB, gC-αA), were produced by recombinant methods. In vitro chaperone-like assays were used to assay the ability of α-crystallins to protect client proteins from chemical or heat induced aggregation. In vivo viability assays were performed in HLE-B3 to determine whether pre-treatment with α-crystallins reduced death after exposure to oxidative or heat stress. Most of the five recombinant α-crystallin proteins tested conferred some in vitro protection from protein aggregation, with the greatest effect seen with WT-αB and gC-αB. All α-crystallins displayed significant protection to oxidative stress induced cell death, while only the αB-crystallins reduced cell death induced by thermal stress. Our findings indicate that the addition of the gC tag enhanced the protective effect of αB-crystallin against oxidative but not thermally-induced cell death. In conclusion, modifications that increase the uptake of α-crystallin proteins into cells, without destroying their chaperone-like activity and anti-apoptotic functions, create the potential to use these proteins therapeutically.     

Altered chaperone-like activity of alpha-crystallins promotes cataractogenesis

Despite the enormous number of studies demonstrating changes in the chaperone-like activity of α-crystallins in vitro, little is known about how these changes influence life-long lens transparency in vivo. Using the γB-crystallin I4F mutant protein as a target for αA-crystallins, we examined how cataract phenotypes are modulated by interactions between α-crystallins with altered chaperone-like activities and γB-I4F proteins in vivo. Double heterozygous α-crystallin knock-out αA(+/-) αB(+/-) mice with a decreased amount of α-crystallins were used to simulate reduced total α-crystallin chaperone-like activity in vivo. We found that triple heterozygous αA(+/-) αB(+/-) γB(I4F/+) mice developed more severe whole cataracts than heterozygous γB(I4F/+) mice. Thus, total chaperone-like activity of α-crystallins is important for maintaining lens transparency. We further tested whether mutant αA-crystallin Y118D proteins with increased chaperone-like activity influenced the whole cataract caused by the γB-I4F mutation. Unexpectedly, compound αA(Y118D/+) γB(I4F/+) mutant lenses displayed severe nuclear cataracts, whereas the lens cortex remained unaffected. Thus, the synergistic effect of αA-Y118D and γB-I4F mutant proteins is detrimental to the transparency only in the lens core. α-Crystallins with different chaperone-like activities are likely required in the lens cortex and nucleus for maintaining transparency.     

Disulfide cross-links in the interaction of a cataract-linked αA-crystallin mutant with βB1-crystallin

A number of αA-crystallin mutants are associated with hereditary cataract including cysteine substitution at arginine 49. We report the formation of affinity-driven disulfide bonds in the interaction of αA-R49C with βB1-crystallin. To mimic cysteine thiolation in the lens, βB1-crystallin was modified by a bimane probe through a disulfide linkage. Our data suggest a mechanism whereby a transient disulfide bond occurs between αA- and βB1-crystallin followed by a disulfide exchange with cysteine 49 of a neighboring αA-crystallin subunit. This is the first investigation of disulfide bonds in the confine of the chaperone/substrate complex where reaction rates are favored by orders of magnitude. Covalent protein cross-links are a hallmark of age-related cataract and may be a factor in its inherited form.     

Calcium-induced decrease of the thermal stability and chaperone activity of α-crystallin

α-Crystallin, one of the major proteins in the vertebrate eye lens, acts as a molecular chaperone, like the small heat-shock proteins, by protecting other proteins from denaturing under stress or high temperature conditions. α-Crystallin aggregation is involved in lens opacification, and high [Ca²⁺] has been associated with cataract formation, suggesting a role for this cation in the pathological process. We have investigated the effect of Ca²⁺ on the thermal stability of α-crystallin by UV and Fourier-transform infrared (FTIR) spectroscopies. In both cases, a Ca²⁺-induced decrease in the midpoint of the thermal transition is detected. The presence of high [Ca²⁺] results also in a marked decrease of its chaperone activity in an insulin-aggregation assay. Furthermore, high Ca²⁺ concentration decreases Cys reactivity towards a sulfhydryl reagent. The results obtained from the spectroscopic analysis, and confirmed by circular dichroism (CD) measurements, indicate that Ca²⁺ decreases both secondary and tertiary–quaternary structure stability of α-crystallin. This process is accompanied by partial unfolding of the protein and a clear decrease in its chaperone activity. It is concluded that Ca²⁺ alters the structural stability of α-crystallin, resulting in impaired chaperone function and a lower protective ability towards other lens proteins. Thus, α-crystallin aggregation facilitated by Ca²⁺ would play a role in the progressive loss of transparency of the eye lens in the cataractogenic process.     

Identification of Isomeric Aspartate residues in βB2-crystallin from Aged Human Lens

Many post-translational modifications such as oxidation, deamidation and isomerization of amino acid residues occur in lens proteins with aging. One such modification, isomerization of aspartate in lens α-crystallin, has been well studied by amino acid enantiomer analysis and LC-MS/MS. LC-MS/MS can quickly and easily identify D- and L-amino acid-containing peptides without purification of lens protein mixtures. However, this method has a weak point in that isomeric peptides of major components are detected predominantly, while those from minor proteins such as β- and γ-crystallins have not been fully determined. Therefore, the isomerization of amino acid residues in β- and γ-crystallin families has been little studied. To solve those problems and detect the isomerization of Asp residues in lens βB2-crystallin, the main component of the β-crystallin family, here we have developed steps for sample fractionation before d/l analysis based on either LC-MS/MS or amino acid derivatization to diastereoisomers followed by RP-HPLC. To capture a small amount of peptide, a multiple reaction monitoring (MRM) method based on quadrupole MS/MS (Q-MS) was applied to the water-soluble fraction of whole lens. The d/l analysis based on both LC-MS/MS and diastereoisomer formation showed the presence of multiple isomerization sites, including Asp4, Asp83, Asp92 and Asp192, in βB2-crystallin in aged lens. These isomerization sites were confirmed to exist in an age-dependent manner by Q-MS. Synthetic peptides of βB2-crystallin containing different isomers of Asp showed differential elution profiles during RP-HPLC, indicating differences in the local structure or hydrophobicity of Asp-isomer-containing peptides. These results suggest that the isomerization sites are distributed on exposed regions of βB2-crystallin and thus likely to have an impact on crystallin subunit–subunit interactions, induce abnormal crystallin aggregation, and contribute to senile cataract formation in aged lens.     

Lens β-crystallins: The role of deamidation and related modifications in aging and cataract

Crystallins are the major proteins in the lens of the eye and function to maintain transparency of the lens. Of the human crystallins, α, β, and γ, the β-crystallins remain the most elusive in their structural significance due to their greater number of subunits and possible oligomer formations. The β-crystallins are also heavily modified during aging. This review focuses on the functional significance of deamidation and the related modifications of racemization and isomerization, the major modifications in β-crystallins of the aged human lens. Elucidating the role of these modifications in cataract formation has been slow, because they are analytically among the most difficult post-translational modifications to study. Recent results suggest that many amides deamidate to similar extent in normal aged and cataractous lenses, while others may undergo greater deamidation in cataract. Mimicking deamidation at critical structural regions induces structural changes that disrupt the stability of the β-crystallins and lead to their aggregation in vitro. Deamidations at the surface disrupt interactions with other crystallins. Additionally, the α-crystallin chaperone is unable to completely prevent deamidated β-crystallins from insolubilization. Therefore, deamidation of β-crystallins may enhance their precipitation and light scattering in vivo contributing to cataract formation.     

A Missense Mutation in CRYBB2 Leads to Progressive Congenital Membranous Cataract by Impacting the Solubility and Function of βB2-Crystallin

Congenital cataract is a major cause of visual impairment and childhood blindness. The solubility and stability of crystallin proteins play critical roles in maintaining the optical transparency of the lens during the life span. Previous studies have shown that approximately 8.3%∼25% of congenital cataracts are inherited, and mutations in crystallins are the most common. In this study, we attempted to identify the genetic defect in a four-generation family affected with congenital cataracts. The congenital cataract phenotype of this four-generation family was identified as membranous cataract by slit-lamp photography. Mutation screening of the candidate genes detected a heterozygous c.465G→C change in the exon6 of the βB2-crystallin gene (CRYBB2) in all family members affected with cataracts, resulting in the substitution of a highly conserved Tryptophan to Cystine (p.W151C). The mutation was confirmed by restriction fragment length polymorphism (RFLP) analysis and found that the transition resulted in the absence of a BslI restriction site in the affected members of the pedigree. The outcome of PolyPhen-2 and SIFT analysis predicted that this W151C mutation would probably damage to the structure and function of βB2-crystallin. Wild type (wt) and W151C mutant βB2-crystallin were expressed in human lens epithelial cells (HLECs), and the fluorescence results showed that Wt-βB2-crystallin was evenly distributed throughout the cells, whereas approximately 34.7% of cells transfected with the W151C mutant βB2-crystallin formed intracellular aggregates. Taken together, these data suggest that the missense mutation in CRYBB2 gene leads to progressive congenital membranous cataract by impacting the solubility and function of βB2-crystallin.     

TXNL6 is a novel oxidative stress-induced reducing system for methionine sulfoxide reductase a repair of α-crystallin and cytochrome C in the eye lens

A key feature of many age-related diseases is the oxidative stress-induced accumulation of protein methionine sulfoxide (PMSO) which causes lost protein function and cell death. Proteins whose functions are lost upon PMSO formation can be repaired by the enzyme methionine sulfoxide reductase A (MsrA) which is a key regulator of longevity. One disease intimately associated with PMSO formation and loss of MsrA activity is age-related human cataract. PMSO levels increase in the eye lens upon aging and in age-related human cataract as much as 70% of total lens protein is converted to PMSO. MsrA is required for lens cell maintenance, defense against oxidative stress damage, mitochondrial function and prevention of lens cataract formation. Essential for MsrA action in the lens and other tissues is the availability of a reducing system sufficient to catalytically regenerate active MsrA. To date, the lens reducing system(s) required for MsrA activity has not been defined. Here, we provide evidence that a novel thioredoxin-like protein called thioredoxin-like 6 (TXNL6) can serve as a reducing system for MsrA repair of the essential lens chaperone α-crystallin/sHSP and mitochondrial cytochrome c. We also show that TXNL6 is induced at high levels in human lens epithelial cells exposed to H(2)O(2)-induced oxidative stress. Collectively, these data suggest a critical role for TXNL6 in MsrA repair of essential lens proteins under oxidative stress conditions and that TXNL6 is important for MsrA defense protection against cataract. They also suggest that MsrA uses multiple reducing systems for its repair activity that may augment its function under different cellular conditions.