NMR spin–echo studies of hydration properties of the molecular chaperone α-crystallin in the bovine lens

The water-binding properties of bovine lens α-crystallin, collagen from calf skin and bovine serum albumin (BSA), were investigated with various techniques. The water absorptive capacity was obtained in high vacuum desorption experiments volumetrically, and also gravimetrically in controlled atmosphere experiments. NMR spin–echo technique was used to study the hydration of protein samples and to determine the spin–spin relaxation times (T₂) from the protons of water, absorbed on the proteins. Isolated bovine lenses were sectioned into 11–12 morphological layers (from anterior cortex through nucleus to posterior cortex). Crystallin profiles were obtained for each lens layer using thin-layer isoelectric focusing in polyacrylamide gel (IEF). The water content in relation to dry weight of proteins was measured in individual morphological lens layers. During the water vapor uptake P/P₀=0.75, α-crystallin did not absorb water, suggesting that hydrophobic regions of the protein are exposed to the aqueous solvent. At P/P₀=1.0, the absorption of water by α-crystallin was 17% with a single component decay character of spin–echo (T₂=3 ms). Addition of water to α-crystallin to about 50% of its w/w in the protein sample showed T₂=8 ms with only one single component decay of the spin–echo signal. The single component decay character of the spin–echo indicates at the tightly bound water by α-crystallin. Under a relative humidity P/P₀=1.0, collagen and BSA absorbed correspondingly 19.3% and 28% of water and showed a two-component decay curve with T₂ of about 5 and 40 ms. The findings demonstrate the presence of two water fractions in collagen and BSA which are separated in space. The IEF data suggest a tight binding of water with α-crystallin with similar distribution patterns in the lens layers. The IEF data demonstrate a possible chaperone-like function for α-crystallin in the nucleus and inner cortex of the lens, but not in the outer cortex. To conclude, it was found that α-crystallin can immobilize and bind water to a greater extent than other proteins such as collagen and BSA. These results shed new light on structural properties of α-crystallin and have important implications for understanding the mechanism of the chaperone-like action of this protein in the lens and non-ocular tissues.     

Hydration Properties of the Molecular Chaperone α-Crystallin in the Bovine Lens

Topographic studies of crystalline fractions from different morphological layers of the young adult bovine lens were conducted. Crystallin profiles were obtained for each lens layer, using thin-layer isoelectric focusing in polyacrylamide gel (IEF). Water soluble (WS) crystallins from the lens equator revealed a separation into HM (high molecular weight) _L-, _H-, _L-, _S-, and -crystallins. The nature of the water insoluble (WI) protein fraction in the separated lens layers reflected the aggregated state of _L-, _L-, _S-, and -crystallins in different regions of the lens, concealed in the central cavity of the -crystallin chaperone model. The IEF data demonstrate a possible chaperone-like function for -crystallin in the nucleus and inner cortex of the lens, but not in the outer cortex. The water binding properties of bovine lens -crystallin, calf skin collagen, and bovine serum albumin (BSA) were investigated with various techniques. The water adsorptive capacity was obtained in high vacuum desorption experiments volumetrically, and also gravimetrically in controlled atmosphere experiments. The NMR spin–-echo technique was used to study the hydration of protein samples and to determine the spin–-spin relaxation times (T₂) from the protons of water adsorbed on the proteins. Isolated bovine lenses were sectioned into 11-12 morphological layers (from anterior cortex through nucleus to posterior cortex). The water content in relation to dry weight of proteins was measured in individual morphological lens layers. During water vapor uptake at relative humidity P/P₀ = 0.75, -crystallin did not adsorb water suggesting that hydrophobic regions of the protein are exposed to the aqueous solvent. At relative humidity P/P₀ = 1.0, the adsorption of water by -crystallin was 17% with a single component decay character of spin echo (T₂ = 3 msec). Addition of water to -crystallin to about 50% of its weight/weight in the protein sample showed T₂ = 8 msec with only one single component decay of the spin–-echo signal. The single component decay character of the spin echo indicates water tightly bound by -crystallin. Under a relative humidity P/P₀ = 1.0, collagen and BSA adsorbed, correspondingly, 19.3 and 28% of water and showed a two-component decay curve with T₂ about 5 and 40 msec. The findings demonstrate the presence of two water fractions in collagen and BSA which are separated in space. The IEF data suggest a tight binding of water with -crystallin with similar distribution patterns in the lens layers. To conclude, it was found that -crystallin can immobilize water to a greater extent than other proteins such as collagen and BSA. These results shed new light on structural properties of -crystallin and its superhydration properties and have important implications for understanding the mechanism of the chaperone-like action of this protein in the lens and non-ocular tissues.     

Delay of diabetic cataract in rats by the antiglycating potential of cumin through modulation of alpha-crystallin chaperone activity

alpha-Crystallin, a molecular chaperone of the eye lens, plays an important role in maintaining the transparency of the lens by preventing the aggregation/inactivation of several proteins and enzymes in addition to its structural role. alpha-Crystallin is a long-lived protein and is susceptible to several posttranslational modifications during aging, more so in certain clinical conditions such as diabetes. Nonenzymatic glycation of lens proteins and decline in the chaperone-like function of alpha-crystallin have been reported in diabetic conditions. Therefore, inhibitors of nonenzymatic protein glycation appear to be a potential target to preserve the chaperone activity of alpha-crystallin and to combat cataract under hyperglycemic conditions. In this study, we investigated the antiglycating potential of cumin in vitro and its ability to modulate the chaperone-like activity of alpha-crystallin vis-à-vis the progression of diabetic cataract in vivo. Aqueous extract of cumin was tested for its antiglycating ability against fructose-induced glycation of goat lens total soluble protein (TSP), alpha-crystallin from goat lens and a nonlenticular protein bovine serum albumin (BSA). The antiglycating potential of cumin was also investigated by feeding streptozotocin (STZ)-induced diabetic rats with diet containing 0.5% cumin powder. The aqueous extract of cumin prevented in vitro glycation of TSP, alpha-crystallin and BSA. Slit lamp examination revealed that supplementation of cumin delayed progression and maturation of STZ-induced cataract in rats. Cumin was effective in preventing glycation of TSP and alpha-crystallin in diabetic lens. Interestingly, feeding of cumin to diabetic rats not only prevented loss of chaperone activity but also attenuated the structural changes of alpha-crystallin in lens. These results indicated that cumin has antiglycating properties that may be attributed to the modulation of chaperone activity of alpha-crystallin, thus delaying cataract in STZ-induced diabetic rats.     

Chaperone-like activity and hydrophobicity of alpha-crystallin

alpha-Crystallin, a prominent member of small heat shock protein (sHsp) family and a major structural protein of the eye lens is a large polydisperse oligomer of two isoforms, alphaA- and alphaB-crystallins. Numerous studies have demonstrated that alpha-crystallin functions like a molecular chaperone in preventing the aggregation of various proteins under a wide range of stress conditions. The molecular chaperone function of alpha-crystallin is thus considered to be vital in the maintenance of lens transparency and in cataract prevention. alpha-Crystallin selectively interacts with non-native proteins thereby preventing them from aggregation and helps maintain them in a folding competent state. It has been proposed and generally accepted that alpha-crystallin suppresses the aggregation of other proteins through the interaction between hydrophobic patches on its surface and exposed hydrophobic sites of partially unfolded substrate protein. However, a quantifiable relationship between hydrophobicity and chaperone-like activity remains a matter to be concerned about. On an attentive review of studies on alpha-crystallin chaperone-like activity, particularly the studies that have direct or indirect implications to hydrophobicity and chaperone-like activity, we found several instances wherein the correlation between hydrophobicity and its chaperone-like activity is paradoxical. We thus attempted to provide an overview on the role of hydrophobicity in chaperone-like activity of alpha-crystallin, the kind of evaluation done for the first time.     

alpha-Crystallin chaperone-like activity and membrane binding in age-related cataracts.

alpha-Crystallin, the major protein component of the vertebrate lens, is thought to play a critical role in the maintenance of transparency through its ability to inhibit stress-induced protein aggregation. However, during aging and cataract formation the amount of membrane-bound alpha-crystallin increases significantly while high molecular weight complexes (HMWCs) comprised of alpha-crystallin and other lens crystallins accumulate. These and other recent data suggest a possible link between cataract formation, the formation of high molecular weight alpha-crystallin aggregates, and the progressive increase in membrane association of alpha-crystallin. To better understand these processes, we characterized the chaperone-like activity (CLA) and subunit exchange of membrane bound alpha-crystallin. In addition, we measured the membrane binding properties of in vitro constituted HMWCs to understand the mechanism by which increased alpha-crystallin is bound to the membrane of old and cataractous lens cells in vivo. Membrane-associated alpha-crystallin complexes have measurably reduced CLA compared to complexes in solution; however, membrane binding does not alter the time required for alpha-crystallin complexes to reach subunit exchange equilibrium. In addition, HMWCs prepared in vitro have a profoundly increased membrane binding capacity as compared to native alpha-crystallin. These results are consistent with a model in which increased membrane binding of alpha-crystallin is an integral step in the pathogenesis of many forms of cataracts.     

Effect of glycation on alpha-crystallin structure and chaperone-like function

The chaperone-like activity of alpha-crystallin is considered to play an important role in the maintenance of the transparency of the eye lens. However, in the case of aging and in diabetes, the chaperone function of alpha-crystallin is compromized, resulting in cataract formation. Several post-translational modifications, including non-enzymatic glycation, have been shown to affect the chaperone function of alpha-crystallin in aging and in diabetes. A variety of agents have been identified as the predominant sources for the formation of AGEs (advanced glycation end-products) in various tissues, including the lens. Nevertheless, glycation of alpha-crystallin with various sugars has resulted in divergent results. In the present in vitro study, we have investigated the effect of glucose, fructose, G6P (glucose 6-phosphate) and MGO (methylglyoxal), which represent the major classes of glycating agents, on the structure and chaperone function of alpha-crystallin. Modification of alpha-crystallin with all four agents resulted in the formation of glycated protein, increased AGE fluorescence, protein cross-linking and HMM (high-molecular-mass) aggregation. Interestingly, these glycation-related profiles were found to vary with different glycating agents. For instance, CML [N(epsilon)-(carboxymethyl)lysine] was the predominant AGE formed upon glycation of alpha-crystallin with these agents. Although fructose and MGO caused significant conformational changes, there were no significant structural perturbations with glucose and G6P. With the exception of MGO modification, glycation with other sugars resulted in decreased chaperone activity in aggregation assays. However, modification with all four sugars led to the loss of chaperone activity as assessed using an enzyme inactivation assay. Glycation-induced loss of alpha-crystallin chaperone activity was associated with decreased hydrophobicity. Furthermore, alpha-crystallin isolated from glycated TSP (total lens soluble protein) had also increased AGE fluorescence, CML formation and diminished chaperone activity. These results indicate the susceptibility of alpha-crystallin to non-enzymatic glycation by various sugars and their derivatives, whose levels are elevated in diabetes. We also describe the effects of glycation on the structure and chaperone-like activity of alpha-crystallin.     

The reaction of alpha-crystallin with the cross-linker 3,3'-dithiobis(sulfosuccinimidyl propionate) demonstrates close proximity of the C termini of alphaA and alphaB in the native assembly

The chaperone-like activity of human lens alpha-crystallin in inhibiting the aggregation of denatured proteins suggests a role for alpha-crystallin in cataract prevention. Although a variety of techniques have generated structural information relevant to its chaperone-like activity, the size and heterogeneity of alpha-crystallin have prevented determination of its crystal structure. Even though synthetic cross-linkers have provided considerable information about protein structures, they have not previously been used to study the proximity and orientation of subunits within human alpha-crystallin. Cross-linkers provide structural insight into proteins by binding the side chains of amino acids within close proximity. To identify the cross-linked residues, the modified protein is digested and the resulting peptides are analyzed by mass spectrometry. Analysis of products from the reaction of alpha-crystallin with 3,3'dithiobis(sulfosuccinimidyl propionate), DTSSP, identified several modifications to both alphaA and alphaB. The most structurally informative of these modifications was a cross-link between lysine 166 of alphaA and lysine 175 of alphaB. This cross-link provides experimental evidence supporting theoretical structural models that place the C termini of alphaA and alphaB within close proximity in the native aggregate.     

The function of alpha-crystallin in vision

The alpha-crystallins account for approximately one-third of the total soluble protein in the lens, contributing to its refractive power. In addition, alpha-crystallin also has a chaperone-like function and thus can bind unfolding lens proteins. Alpha B-crystallin is also found outside the lens, having an extensive tissue distribution. It is over-expressed in response to stresses of all kinds, where it is thought to serve a general protective function. Recently, it has been shown in humans that naturally occurring point mutations in the alpha-crystallins result in a deficit in chaperone-like function, and cause cataracts as well as a desmin-related myopathy. This review summarizes much of the past and current knowledge concerning the structure and functions of alpha-crystallin.     

Structural perturbation and enhancement of the chaperone-like activity of alpha-crystallin by arginine hydrochloride

Structural perturbation of alpha-crystallin is shown to enhance its molecular chaperone-like activity in preventing aggregation of target proteins. We demonstrate that arginine, a biologically compatible molecule that is known to bind to the peptide backbone and negatively charged side-chains, increases the chaperone-like activity of calf eye lens alpha-crystallin as well as recombinant human alphaA- and alphaB-crystallins. Arginine-induced increase in the chaperone activity is more pronounced for alphaB-crystallin than for alphaA-crystallin. Other guanidinium compounds such as aminoguanidine hydrochloride and guanidine hydrochloride also show a similar effect, but to different extents. A point mutation, R120G, in alphaB-crystallin that is associated with desmin-related myopathy, results in a significant loss of chaperone-like activity. Arginine restores the activity of mutant protein to a considerable extent. We have investigated the effect of arginine on the structural changes of alpha-crystallin by circular dichroism, fluorescence, and glycerol gradient sedimentation. Far-UV CD spectra show no significant changes in secondary structure, whereas near-UV CD spectra show subtle changes in the presence of arginine. Glycerol gradient sedimentation shows a significant decrease in the size of alpha-crystallin oligomer in the presence of arginine. Increased exposure of hydrophobic surfaces of alpha-crystallin, as monitored by pyrene-solubilization and ANS-fluorescence, is observed in the presence of arginine. These results show that arginine brings about subtle changes in the tertiary structure and significant changes in the quaternary structure of alpha-crystallin and enhances its chaperone-like activity significantly. This study should prove useful in designing strategies to improve chaperone function for therapeutic applications.     

Effect of hydrostatic pressure on quaternary structure on the chaperone function of alpha-crystallin

High hydrostatic pressure-induced changes in bovine lens alpha-crystallin oligomers size and chaperone-like function were studied by a static light scattering. Under pressure 1.5 kbar, alpha-crystallin oligomers size is almost unaffected. Increase of the size was observed during several hours of incubation at 3 kbar. Such high-pressure effect on association has been previously revealed for detergent micelles, whereas the "typical" protein oligomers are known to dissociate under high pressure. Our results about pressure influence on alpha-crystallin association supports the previously proposed "protein micelle" model of the protein quaternary structure. Chaperone-like activity of alpha-crystallin is shown to increase after incubation at 3 kbar. After the end of the incubation this activity is slowly decreasing during several hours.     

Correlation between the chaperone-like activity and aggregate size of alpha-crystallin with increasing temperature

alpha-Crystallin, the major protein of the mammalian eye lens, is also found in the major tissues of the body, where one or the other of its two isoforms is characteristically expressed. Both isoform sequences are highly related to others of the small heat shock protein superfamily, leading to speculation about their functions in vivo outside of the lens. Tests of chaperone-like activity at 37 and 66 degrees C indicate that the protein can act to prevent the superaggregation of partially denatured proteins, but both alpha-crystallin aggregate size and shape are significantly altered with increasing temperature. Characterization of these changes indicates that secondary, tertiary, and quaternary structure are modified, with the latter effect especially striking above 50 degrees C. Furthermore, these changes appear to be irreversible when the temperature is returned to 25 or 37 degrees C. Functionally, the protein is effective in chaperone-like activity at all temperatures, but exhibits a somewhat increased capability after a cycle of heating and cooling. The results presented here indicate the heat-induced formation of high-molecular-weight aggregates of alpha-crystallin is a slow progressive process. The increased activity of these aggregates suggests that chaperone-like activity depends in part on the packing parameters of the aggregate and on conformation of the subunit within that aggregate.     

Temperature effects on alpha-crystallin structure probed by 6-bromomethyl-2-(2-furanyl)-3-hydroxychromone, an environmentally sensitive two-wavelength fluorescent dye covalently attached to the single Cys residue

The single Cys residue in the C-terminal domain of bovine eye lens alpha-crystallin was covalently labelled with 6-bromomethyl-2-(2-furanyl)-3-hydroxychromone. This novel SH-reactive two-band ratiometric fluorescent dye is characterized by excited state intramolecular proton transfer reaction yielding two highly emissive N* and T* bands separated by more than 100 nm. Their relative intensities are known to be highly sensitive to the H-bonding ability of the environment. Properties of the environment of the dye attached to the protein were studied under native-like conditions and at a range of elevated temperatures that are known to facilitate alpha-crystallin chaperone-like activity. We observe that on heating, the environment of the dye becomes more flexible and the H-bonding of the dye with the protein vicinity decreases. The spectroscopic properties observed on heating were partially restored after cooling, but the initial values were not reached on the time scale of our experiments (up to 3 h). This suggests that the changes of the dye microenvironment are connected with the rearrangements of alpha-crystallin quaternary structure. Since there is only one Cys residue in alphaA subunit of alpha-crystallin (whereas alphaB subunit contains no Cys), we attributed the observed temperature-induced changes of the dye's microenvironment to the particular site within alpha-crystallin molecule.     

Packing-induced conformational and functional changes in the subunits of alpha -crystallin

The heteroaggregate alpha-crystallin and homoaggregates of its subunits, alphaA- and alphaB-crystallins, function like molecular chaperones and prevent the aggregation of several proteins. Although modulation of the chaperone-like activity of alpha-crystallin by both temperature and chaotropic agents has been demonstrated in vitro, the mechanism(s) of its regulation in vivo have not been elucidated. The subunits of alpha-crystallin exchange freely, resulting in its dynamic and variable quaternary structure. Mixed aggregates of the alpha-crystallins and other mammalian small heat shock proteins (sHSPs) have also been observed in vivo. We have investigated the time-dependent structural and functional changes during the course of heteroaggregate formation by the exchange of subunits between homoaggregates of alphaA- and alphaB-crystallins. Native isoelectric focusing was used to follow the time course of subunit exchange. Circular dichroism revealed large tertiary structural alterations in the subunits upon subunit exchange and packing into heteroaggregates, indicating specific homologous and heterologous interactions between the subunits. Subunit exchange also resulted in quaternary structural changes as demonstrated by gel filtration chromatography. Interestingly, we found time-dependent changes in chaperone-like activity against the dithiothreitol-induced aggregation of insulin, which correlated with subunit exchange and the resulting tertiary and quaternary structural changes. Heteroaggregates of varying subunit composition, as observed during eye lens epithelial cell differentiation, generated by subunit exchange displayed differential chaperone-like activity. It was possible to alter chaperone-like activity of preexisting oligomeric sHSPs by alteration of subunit composition by subunit exchange. Our results demonstrate that subunit exchange and the resulting structural and functional changes observed could constitute a mechanism of regulation of chaperone-like activity of alpha-crystallin (and possibly other mammalian sHSPs) in vivo.     

Transglutaminase-mediated cross-linking of alpha-crystallin: structural and functional consequences.

Aggregation and covalent cross-linking of the crystallins, the major structural proteins of the eye lens, increase light scattering by the lens leading to opacification and cataract. Disturbance of calcium homeostasis in the tissue is one of the factors implicated in cataractogenesis. Calcium-activated transglutaminase (TG)-catalyzed cross-linking of some lens proteins has been reported earlier. We show here that alpha-crystallin, a major structural protein in the lens and a member of the small heat shock protein family, is also a substrate for TG-mediated cross-linking, indicating the presence of donor Lys and acceptor Gln residues in the protein. Upon TG-catalyzed dimerization, the secondary and tertiary structures of the protein are altered, and its surface hydrophobicity reduced. The chaperone-like property of the protein, suspected to be one of its functions in situ, is substantially reduced upon such cross-linking. These results, taken together with earlier ones on lens beta-crystallins and vimentin, suggest that TG-mediated events might compromise lens function. Also, since alpha-crystallin occurs not only in the lens but in other tissues as well, such TG-catalyzed cross-linking and the associated alterations in its structure and activity would be of general pathological interest.     

The apparent molecular size of native alpha-crystallin B in non-lenticular tissues

The apparent molecular size of the native alpha-crystallin B in cytosol preparations from rat heart, brain and retina was determined by gel permeation chromatography, detecting the protein by immunochemical assay (ELISA), using an alpha-crystallin specific antiserum. Native alpha-crystallin from cytosol preparations of rat lens cortex was used as a reference. alpha-Crystallin B present in all three cytosol preparations from non-lenticular tissues eluted in a single symmetrical peak, with the same elution volume as alpha-crystallin from lens cortex cytosol preparations, corresponding to an apparent average molecular size of 0.8 x 10(6) Da. No other species could be detected. The results indicate that the alpha-crystallin aggregates characterized by an apparent average molecular mass of 0.8 x 10(6) Da, and considered to be the native, physiological form of the protein in the lens, are indeed not specific to lens tissue. Furthermore, the size of these alpha-crystallin aggregates is independent of their polypeptide composition. Aggregates found in the lens, composed of alpha A and alpha B polypeptides and their respective phosphorylated forms alpha Ap and alpha Bp, are similar in size to those found in heart, brain and retina, containing the alpha B but not the alpha A polypeptide.     

Heat perturbation of bovine eye lens alpha-crystallin probed by covalently attached ratiometric fluorescent dye 4'-diethylamino-3-hydroxyflavone

Bovine eye lens alpha-crystallin was covalently labeled with 6-bromomethyl-4'-diethylamino-3-hydroxyflavone and studied under native-like conditions and at the elevated temperature (60 degrees C) that is known to facilitate alpha-crystallin chaperone-like activity. This novel SH-reactive two-band ratiometric fluorescent probe is characterized by two highly emissive N*- and T*-bands; the latter appears due to excited state intramolecular proton transfer reaction. The positions of these bands and the ratio of their intensities for the alpha-crystallin-dye conjugate are the sensitive indicators of polarity of the dye environment and its participation in intermolecular hydrogen bonding. Although we found that the dye labels both the SH and the NH2 groups in alpha-crystallin, a recently developed procedure allowed us to distinguish between the heat-induced spectral changes of the dye molecules attached to SH and NH2 groups. We observed that at elevated temperature the environment of the SH-attached dye becomes more polar and flexible. The number of H-bond acceptor groups in the vicinity of the dye decreases. Since alpha-crystallin contains a single Cys residue within the C-terminal domain of its (alpha)A subunit (the (alpha)B subunit contains none), we can attribute the observed effects to temperature-induced changes in the C-terminal domain of this protein.     

Significance of alpha-crystallin heteropolymer with a 3:1 alphaA/alphaB ratio: chaperone-like activity, structure and hydrophobicity

The small heat-shock protein alpha-crystallin isolated from the eye lens exists as a large (700 kDa) heteropolymer composed of two subunits, alphaA and alphaB, of 20 kDa each. Although trace amounts of alphaA-crystallin are found in other tissues, non-lenticular distribution of alpha-crystallin is dominated by the alphaB homopolymer. In most vertebrate lens, the molar ratio of alphaA to alphaB is generally 3:1. However, the importance of this ratio in the eye lens is not known. In the present study, we have investigated the physiological significance of the 3:1 ratio by determining the secondary/tertiary structure, hydrophobicity and chaperone-like activity of alphaA- and alphaB-homopolymers and heteropolymers with different ratios of alphaA to alphaB subunits. Although, under physiologically relevant conditions, the alphaB-homopolymer (37-40 degrees C) has shown relatively higher activity, the alphaA-homopolymer or the heteropolymer with a higher alphaA proportion (3:1 ratio) has shown greater chaperone-like activity at elevated temperatures (>50 degrees C) and also upon structural perturbation. Furthermore, higher chaperone activity at elevated temperatures as well as upon structural perturbation is mainly mediated through increased hydrophobicity of alphaA. Although homopolymers and heteropolymers of alpha-crystallin did not differ in their secondary structure, changes in tertiary structure due to structural perturbations upon pre-heating are mediated predominantly by alphaA. Interestingly, the heteropolymer with higher alphaA proportion (3:1) or the alphaA-homopolymer seems to be better chaperones in protecting lens beta- and gamma-crystallins at both normal and elevated temperatures. Thus lens might have favoured a combination of these qualities to achieve optimal protection under both native and stress (perturbed) conditions for which the heteropolymer with alphaA to alphaB in the 3:1 ratio appears to be better suited.     

Differential temperature-dependent chaperone-like activity of alphaA- and alphaB-crystallin homoaggregates

alpha-Crystallin, a heteromultimeric protein made up of alphaA- and alphaB-crystallins, functions as a molecular chaperone in preventing the aggregation of proteins. We have shown earlier that structural perturbation of alpha-crystallin can enhance its chaperone-like activity severalfold. The two subunits of alpha-crystallin have extensive sequence homology and individually display chaperone-like activity. We have investigated the chaperone-like activity of alphaA- and alphaB-crystallin homoaggregates against thermal and nonthermal modes of aggregation. We find that, against a nonthermal mode of aggregation, alphaB-crystallin shows significant protective ability even at subphysiological temperatures, at which alphaA-crystallin or heteromultimeric alpha-crystallin exhibit very little chaperone-like activity. Interestingly, differences in the protective ability of these homoaggregates against the thermal aggregation of beta(L)-crystallin is negligible. To investigate this differential behavior, we have monitored the temperature-dependent structural changes in both the proteins using fluorescence and circular dichroism spectroscopy. Intrinsic tryptophan fluorescence quench-ing by acrylamide shows that the tryptophans in alphaB-crystallin are more accessible than the lone tryptophan in alphaA-crystallin even at 25 degrees C. Protein-bound 8-anilinonaphthalene-1-sulfonate fluorescence demonstrates the higher solvent accessibility of hydrophobic surfaces on alphaB-crystallin. Circular dichroism studies show some tertiary structural changes in alphaA-crystallin above 50 degrees C. alphaB-crystallin, on the other hand, shows significant alteration of tertiary structure by 45 degrees C. Our study demonstrates that despite a high degree of sequence homology and their generally accepted structural similarity, alphaB-crystallin is much more sensitive to temperature-dependent structural perturbation than alphaA- or alpha-crystallin and shows differences in its chaperone-like properties. These differences appear to be relevant to temperature-dependent enhancement of chaperone-like activity of alpha-crystallin and indicate different roles for the two proteins both in alpha-crystallin heteroaggregate and as separate proteins under stress conditions.     

A novel quaternary structure of the dimeric alpha-crystallin domain with chaperone-like activity

alphaB-crystallin, a member of the small heat-shock protein family and a major eye lens protein, is a high molecular mass assembly and can act as a molecular chaperone. We report a synchrotron radiation x-ray solution scattering study of a truncation mutant from the human alphaB-crystallin (alphaB57-157), a dimeric protein that comprises the alpha-crystallin domain of the alphaB-crystallin and retains a significant chaperone-like activity. According to the sequence analysis (more than 23% identity), the monomeric fold of the alpha-crystallin domain should be close to that of the small heat-shock protein from Methanococcus jannaschii (MjHSP16.5). The theoretical scattering pattern computed from the crystallographic model of the dimeric MjHSP16.5 deviates significantly from the experimental scattering by the alpha-crystallin domain, pointing to different quaternary structures of the two proteins. A rigid body modeling against the solution scattering data yields a model of the alpha-crystallin domain revealing a new dimerization interface. The latter consists of a strand-turn-strand motif contributed by each of the monomers, which form a four-stranded, antiparallel, intersubunit composite beta-sheet. This model agrees with the recent spin labeling results and suggests that the alphaB-crystallin is composed by flexible building units with an extended surface area. This flexibility may be important for biological activity and for the formation of alphaB-crystallin complexes of variable sizes and compositions.