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

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

Deamidation, but not truncation, decreases the urea stability of a lens structural protein, betaB1-crystallin

Crystallins, the major structural proteins in the lens of the eye, are maintained with little turnover throughout the lifetime of the host. With time, lens crystallins undergo post-translational modifications that may play an important role in loss of vision during aging and cataract formation. Specific modifications include deamidation and truncation. Urea-induced denaturation was studied for recombinantly expressed wild-type betaB1 (WT), the deamidated mutant (Q204E), an N-terminally truncated mutant (betaB1(DeltaN41)), and other truncated versions of these proteins generated by calpain II digestion. Tryptophan fluorescence was used to monitor loss of global tertiary structure. Loss of secondary structure was followed by circular dichroism, and electron paramagnetic resonance site-directed spin labeling was used to monitor loss of tertiary structure selectively in the N-terminal domain. Our results indicated that the deamidated mutant was significantly destabilized relative to WT. Q204E showed a two-step denaturation curve with transitions at 4.1 and 7.2 M urea, whereas denaturation of WT occurred in a cooperative single step with a transition midpoint of 5.9 M urea. Unfolding of WT was completely reversible, whereas Q204E failed to fully refold. Prolonged incubation under denaturing conditions led to aggregation, which was also more pronounced for Q204E dimers than for WT. Truncation of 41 residues from the N-terminus or 47 and 5 residues from the N- and C-termini did not affect stability. These studies indicated that a single-site deamidation could significantly diminish the stability of lens betaB1-crystallin, supporting the idea that such modifications may play an important role in age-related cataract formation.     

Deamidation in human lens betaB2-crystallin destabilizes the dimer

Two major determinants of the transparency of the lens are protein-protein interactions and stability of the crystallins, the structural proteins in the lens. betaB2 is the most abundant beta-crystallin in the human lens and is important in formation of the complex interactions of lens crystallins. betaB2 readily forms a homodimer in vitro, with interacting residues across the monomer-monomer interface conserved among beta-crystallins. Due to their long life spans, crystallins undergo an unusually large number of modifications, with deamidation being a major factor. In this study the effects of two potential deamidation sites at the monomer-monomer interface on dimer formation and stability were determined. Glutamic acid substitutions were constructed to mimic the effects of previously reported deamidations at Q162 in the C-terminal domain and at Q70, its N-terminal homologue. The mutants had a nativelike secondary structure similar to that of wild type betaB2 with differences in tertiary structure for the double mutant, Q70E/Q162E. Multiangle light scattering and quasi-elastic light scattering experiments showed that dimer formation was not interrupted. In contrast, equilibrium unfolding and refolding in urea showed destabilization of the mutants, with an inflection in the transition of unfolding for the double mutant suggesting a distinct intermediate. These results suggest that deamidation at critical sites destabilizes betaB2 and may disrupt the function of betaB2 in the 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.     

Laser light-scattering evidence for an altered association of beta B1-crystallin deamidated in the connecting peptide

Deamidation is a prevalent modification of crystallin proteins in the vertebrate lens. The effect of specific sites of deamidation on crystallin stability in vivo is not known. Using mass spectrometry, a previously unreported deamidation in beta B1-crystallin was identified at Gln146. Another deamidation was investigated at Asn157. It was determined that whole soluble beta B1 contained 13%-17% deamidation at Gln146 and Asn157. Static and quasi-elastic laser light scattering, circular dichroism, and heat aggregation studies were used to explore the structure and associative properties of recombinantly expressed wild-type (wt) beta B1 and the deamidated beta B1 mutants, Q146E and N157D. Dimer formation occurred for wt beta B1, Q146E, and N157D in a concentration-dependent manner, but only Q146E showed formation of higher ordered oligomers at the concentrations studied. Deamidation at Gln146, but not Asn157, led to an increased tendency of beta B1 to aggregate upon heating. We conclude that deamidation creates unique effects depending upon where the deamidation is introduced in the crystallin structure.     

Monomer-dimer equilibrium of normal and modified beta A3-crystallins: experimental determination and molecular modeling

Beta- and gamma-crystallins are major protein constituents of the mammalian lens, where their stability and association into higher order complexes are critical for clarity and refraction. Two regions of the betagamma-crystallins have been suggested to modulate protein association, namely, the flexible N-terminal extensions and the intramolecular domain interfaces. The oligomeric state of wild-type recombinant murine betaA3-crystallin (rbetaA3) was compared to that of modified betaA3-crystallins with either an N-terminal deletion of residues 1 to 29 (rbetaA3tr) or with residues 114 to 123 of the interdomain linker replaced with the analogous linker from murine gammaB-crystallin (rbetaA3cp). All three proteins exhibited reversible monomer-dimer formation. The modifications to the N-terminus and domain linker resulted in tighter dimer formation as compared to wild-type protein as indicated by disassociation constants determined by sedimentation equilibrium: 6.62 x 10(-6) M (rbetaA3), 0.86 x 10(-6) M (rbetaA3cp), and 1.83 x 10(-7) M (rbetaA3tr). Homology modeling of betaA3-crystallins and solvation energy calculations also predicted tighter binding of the modified crystallins consistent with the centrifugation results. The findings suggest that under physiological conditions betaA3 crystallin exists in a dynamic equilibrium between monomeric and dimeric protein and that modification, especially to the N-terminal extension, can promote self-association.     

Modifications of human betaA1/betaA3-crystallins include S-methylation, glutathiolation, and truncation

Disulfide bonding of lens crystallins contributes to the aggregation and insolubilization of these proteins that leads to cataract. A high concentration of reduced glutathione is believed to be key in preventing oxidation of crystallin sulfhydryls to form disulfide bonds. This protective role is decreased in aged lenses because of lower glutathione levels, especially in the nucleus. We recently found that human gamma-crystallins undergo S-methylation at exposed cysteine residues, a reaction that may prevent disulfide bonding. We report here that betaA1/A3-crystallins are also methylated at specific cysteine residues and are the most heavily methylated of the human lens crystallins. Among the methylated sites, Cys 64, Cys 99, and Cys 167 of betaA1-crystallin, methylation at Cys 99 is highest. Cys 64 and Cys 99 are also glutathiolated, even in a newborn lens. These post-translational modifications of the exposed cysteines may be important for maintaining the crystallin structure required for lens transparency. Previously unreported N-terminal truncations were also found.     

Cumulative deamidations of the major lens protein γS‐crystallin increase its aggregation during unfolding and oxidation

Age‐related lens cataract is the major cause of blindness worldwide. The mechanisms whereby crystallins, the predominant lens proteins, assemble into large aggregates that scatter light within the lens, and cause cataract, are poorly understood. Due to the lack of protein turnover in the lens, crystallins are long‐lived. A major crystallin, γS, is heavily modified by deamidation, in particular at surface‐exposed N14, N76, and N143 to introduce negative charges. In this present study, deamidated γS was mimicked by mutation with aspartate at these sites and the effect on biophysical properties of γS was assessed via dynamic light scattering, chemical and thermal denaturation, hydrogen‐deuterium exchange, and susceptibility to disulfide cross‐linking. Compared with wild type γS, a small population of each deamidated mutant aggregated rapidly into large, light‐scattering species that contributed significantly to the total scattering. Under partially denaturing conditions in guanidine hydrochloride or elevated temperature, deamidation led to more rapid unfolding and aggregation and increased susceptibility to oxidation. The triple mutant was further destabilized, suggesting that the effects of deamidation were cumulative. Molecular dynamics simulations predicted that deamidation augments the conformational dynamics of γS. We suggest that these perturbations disrupt the native disulfide arrangement of γS and promote the formation of disulfide‐linked aggregates. The lens‐specific chaperone αA‐crystallin was poor at preventing the aggregation of the triple mutant. It is concluded that surface deamidations cause minimal structural disruption individually, but cumulatively they progressively destabilize γS‐crystallin leading to unfolding and aggregation, as occurs in aged and cataractous lenses.     

Simultaneous stereoinversion and isomerization at the Asp-4 residue in βB2-crystallin from the aged human eye lenses

The lens proteins are composed of α-, β-, and γ-crystallins that interact with each other to maintain the transparency and refractive power of the lens. Because the lens crystallins are long-lived proteins, they undergo various post-translational modifications including racemization, isomerization, deamidation, oxidation, glycation, and truncation. In βB2-crystallin, which is the most abundant β-crystallin, the deamidation of asparagine and glutamine residues has been reported. Here, we found that the aspartyl (Asp) residue at position 4 of βB2-crystallin in the lenses of elderly human individuals undergoes a significant degree of inversion and isomerization to the biologically uncommon residue D-β-Asp. Surprisingly, the D/L ratio of β-Asp at position 4 in βB2-crystallin from elderly donors (67-77 year old) was 0.88-3.21. A D/L ratio of amino acids greater than 1.0 is defined as an inversion of configuration from the L- to D-form, rather than a racemization. These extremely high D/L ratios are equivalent to those of Asp-58 and Asp-151 (D/L ratio: 3.1 for Asp-58 and 5.7 for Asp-151) in αA-crystallin from elderly donors (~80 year old) as reported previously. Initially, we identified specific Asp residues in the β-crystallin family of proteins that undergo a high degree of inversion. These results show that the isomerization and inversion of Asp residues occurs both in the α- and β-crystallins of the lens. Inversion of these Asp residues directly affects the higher order structure of the protein. Hence, this modification may change crystallin-crystallin interactions and disrupt the function of crystallins in the lens.     

Glutamine deamidation destabilizes human gammaD-crystallin and lowers the kinetic barrier to unfolding

Human eye lens transparency requires life long stability and solubility of the crystallin proteins. Aged crystallins have high levels of covalent damage, including glutamine deamidation. Human gammaD-crystallin (HgammaD-Crys) is a two-domain beta-sheet protein of the lens nucleus. The two domains interact through interdomain side chain contacts, including Gln-54 and Gln-143, which are critical for stability and folding of the N-terminal domain of HgammaD-Crys. To test the effects of interface deamidation on stability and folding, single and double glutamine to glutamate substitutions were constructed. Equilibrium unfolding/refolding experiments of the proteins were performed in guanidine hydrochloride at pH 7.0, 37 degrees C, or urea at pH 3.0, 20 degrees C. Compared with wild type, the deamidation mutants were destabilized at pH 7.0. The proteins populated a partially unfolded intermediate that likely had a structured C-terminal domain and unstructured N-terminal domain. However, at pH 3.0, equilibrium unfolding transitions of wild type and the deamidation mutants were indistinguishable. In contrast, the double alanine mutant Q54A/Q143A was destabilized at both pH 7.0 and 3.0. Thermal stabilities of the deamidation mutants were also reduced at pH 7.0. Similarly, the deamidation mutants lowered the kinetic barrier to unfolding of the N-terminal domain. These data indicate that interface deamidation decreases the thermodynamic stability of HgammaD-Crys and lowers the kinetic barrier to unfolding due to introduction of a negative charge into the domain interface. Such effects may be significant for cataract formation by inducing protein aggregation or insolubility.     

The molecular refractive function of lens γ-Crystallins

γ-Crystallins constitute the major protein component in the nucleus of the vertebrate eye lens. Present at very high concentrations, they exhibit extreme solubility and thermodynamic stability to prevent scattering of light and formation of cataracts. However, functions beyond this structural role have remained mostly unclear. Here, we calculate molecular refractive index increments of crystallins. We show that all lens γ-crystallins have evolved a significantly elevated molecular refractive index increment, which is far above those of most proteins, including nonlens members of the βγ-crystallin family from different species. The same trait has evolved in parallel in crystallins of different phyla, including S-crystallins of cephalopods. A high refractive index increment can lower the crystallin concentration required to achieve a suitable refractive power of the lens and thereby reduce their propensity to aggregate and form cataracts. To produce a significant increase in the refractive index increment, a substantial global shift in amino acid composition is required, which can naturally explain the highly unusual amino acid composition of γ-crystallins and their functional homologues. This function provides a new perspective for interpreting their molecular structure.     

Deamidation in human gamma S-crystallin from cataractous lenses is influenced by surface exposure

A major component of human nuclear cataracts is water-insoluble, high molecular weight protein. A significant component of this protein is disulfide bonded gamma S-crystallin that can be reduced to monomers by dithiothreitol. Analysis of this reduced gamma S-crystallin showed that deamidation of glutamine and asparagine residues is a principal modification. Deamidation is one of the modifications of lens crystallins associated with aging and cataractogenesis. One proposed hypothesis of cataractogenesis is that it develops in response to altered surface charges that cause conformational changes, which, in turn, permit formation of disulfide bonds and crystallin insolubility. This report, showing deamidation among the disulfide bonded gamma S-crystallins from cataractous lenses, supports this hypothesis.     

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.     

Significance of interactions of low molecular weight crystallin fragments in lens aging and cataract formation

Analysis of aged and cataract lenses shows the presence of increased amounts of crystallin fragments in the high molecular weight aggregates of water-soluble and water-insoluble fractions. However, the significance of accumulation and interaction of low molecular weight crystallin fragments in aging and cataract development is not clearly understood. In this study, 23 low molecular mass (<3.5-kDa) peptides in the urea-soluble fractions of young, aged, and aged cataract human lenses were identified by mass spectroscopy. Two peptides, alphaB-(1-18) (MDIAIHHPWIRRPFFPFH) and betaA3/A1-(59-74) (SD(N)AYHIERLMSFRPIC), present in aged and cataract lens but not young lens, and a third peptide, gammaS-(167-178) (SPAVQSFRRIVE) present in all three lens groups were synthesized to study the effects of interaction of these peptides with intact alpha-, beta-, and gamma-crystallins and alcohol dehydrogenase, a protein used in aggregation studies. Interaction of alphaB-(1-18) and betaA3/A1-(59-74) peptides increased the scattering of light by beta- and gamma-crystallin and alcohol dehydrogenase. The ability of alpha-crystallin subunits to function as molecular chaperones was significantly reduced by interaction with alphaB-(1-18) and betaA3/A1-(59-74) peptides, whereas gammaS peptide had no effect on chaperone-like activity of alpha-crystallin. The betaA3/A1-(59-74 peptide caused a 5.64-fold increase in alphaB-crystallin oligomeric mass and partial precipitation. Replacing hydrophobic residues in alphaB-(1-18) and betaA3/A1-(59-74) peptides abolished their ability to induce crystallin aggregation and light scattering. Our study suggests that interaction of crystallin-derived peptides with intact crystallins could be a key event in age-related protein aggregation in lens and cataractogenesis.     

Truncation of motifs III and IV in human lens betaA3-crystallin destabilizes the structure

The purpose of our study was to determine the effects of specific truncations on the structural properties of human betaA3-crystallin. The following eight deletion mutants of betaA3-crystallin were generated: (i) N-terminal extension (NTE) 21 amino acids (betaA3[21] mutant), (ii) NTE 22 amino acids (betaA3[22] mutant), (iii) NTE (betaA3[N] mutant), (iv) NTE plus motif I (betaA3[N+I] mutant), (v) NTE plus motifs I and II (betaA3[N+I+II] mutant), (vi) NTE plus motifs I and II and connecting peptide (betaA3[N+I+II+CP] mutant), (vii) motifs III and IV (betaA3[III+IV] mutant), and (viii) motif IV (betaA3 [IV] mutant). The DNA sequencing and MALDI-TOF mass spectrometric methods confirmed desired specific deletions, and the purified mutant proteins exhibited a single band during SDS-PAGE analysis. When ANS bound, all the mutant proteins exhibited fluorescence quenching and a red shift, suggesting that the truncations caused changes in the exposed hydrophobic patches. The CD spectra showed that deletion of either NTE or the N-terminal domain (motifs I and II) had a relatively weaker effect on the structural stability than deletion of the C-terminal domain (motifs III and IV). Intrinsic Trp fluorescence spectral studies suggested changes in the microenvironment of the mutant proteins following truncations. HPLC multiangle light scattering analyses showed that truncation led to higher-order aggregation compared to that in the wild-type protein. Equilibrium unfolding and refolding of WT betaA3 with urea were best fit to a three-state model with transition midpoints at 2.2 and 3.1 M urea. However, the two transition midpoints of betaA3[21] and betaA3[22] and betaA3[N] mutants were similar to those of the wild type, suggesting that these truncations had a minimal effect on structural stabilization. Further, the mutant proteins containing the N-terminal domain (i.e., betaA3[III+IV] and betaA3[IV] mutants) exhibited higher transition midpoints compared to the transition midpoints of the mutant protein with the C-terminal domain (i.e., betaA3[N+I+II+CP] mutant). The results suggested that the N-terminal domain is relatively more stable than the C-terminal domain in betaA3-crystallin.     

Changes in proteins of the human lens in development and aging.

A number of proteins have been isolated from the human lens at different stages of development, from before birth to old age. These proteins have been characterized and compared with each other and with corresponding proteins from bovine lens. Many similarities were found between human and bovine crystallins, but alpha-crystallin isolated from old human lenses using DEAE-cellulose, unlike bovine alpha-crystallin similarly isolated, is not found as large soluble aggregates. The amide contents of various lens protein fractions were determined. No extensive changes were found during adult life, but there was evidence that significant deamidation of alpha-crystallin had occurred before birth and possibly during infancy. The results are related to the unique development and aging of the lens.     

Formation of betaA3/betaB2-crystallin mixed complexes: involvement of N- and C-terminal extensions.

The sequence extensions of the beta-crystallin subunits have been suggested to play an important role in the oligomerization of these eye lens proteins. This, in turn, may contribute to maintaining lens transparency and proper light refraction. In homo-dimers of the betaA3- and betaB2-crystallin subunits, these extensions have been shown by (1)H-NMR spectroscopy to be solvent-exposed and highly flexible. In this study, we show that betaA3- and betaB2-crystallins spontaneously form mixed betaA3/betaB2-crystallin complexes, which, from analytical ultracentrifugation experiments, are dimeric at low concentrations (<1 mg ml(-1)) and tetrameric at higher protein concentrations. (1)H-NMR spectroscopy reveals that in the betaA3/betaB2-crystallin tetramer, the N-terminal extensions of betaA3-crystallin remain water-exposed and flexible, whereas both N- and C-terminal extensions of betaB2-crystallin lose their flexibility. We conclude that both extensions of betaB2-crystallin are involved in protein-protein interactions in the betaA3/betaB2-crystallin hetero-tetramer. The extensions may stabilize and perhaps promote the formation of this mixed complex.     

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.     

In vivo heteromer formation. Expression of soluble betaA4-crystallin requires coexpression of a heteromeric partner

The beta-crystallins are a family of long-lived, abundant structural proteins that are coexpressed in the vertebrate lens. As beta-crystallins form heteromers, a process that involves transient exposure of hydrophobic interfaces, we have examined whether in vivobeta-crystallin assembly is enhanced by protein chaperones, either small heat shock proteins, Hsp27 or alphaB-crystallin, or Hsp70. We show here that betaA4-crystallin is abundantly expressed in HeLa cells, but rapidly degraded, irrespective of the presence of Hsp27, alphaB-crystallin or Hsp70. Degradation is even enhanced by Hsp70. Coexpression of betaA4-crystallin with betaB2-crystallin yielded abundant soluble betaA4-betaB2-crystallin heteromers; betaB1-crystallin was much less effective in solubilizing betaA4-crystallin. As betaB2-crystallin competed for betaA4-crystallin with Hsp70 and the proteasomal degradation pathway, betaB2-crystallin probably captures an unstable betaA4-crystallin intermediate. We suggest that the proper folding of betaA4-crystallin is not mediated by general chaperones but requires a heteromeric partner, which then also acts as a dedicated chaperone towards betaA4-crystallin.