Phosphorylation negatively regulates exosome mediated secretion of cryAB in glioma cells.

Exosomes mediate secretion of crystallin alphaB (cryAB), a well characterized molecular chaperone with anti-apoptotic activity. However, the mechanisms governing its packaging and secretion remained unexplored. In glioma cells, notwithstanding extensive phosphorylation of cryAB at Ser59 followed by Ser45 (Ser19 is largely unphosphorylated), we discovered that the majority of secreted exosomal cryAB is nonphosphorylated. Transient ectopic expression of a yellow fluorescent protein (YFP) tagged triple phosphomimic (3-SD) cryAB construct in cryAB absent glioma cells led to the formation of large cytosolic inclusions. Our findings demonstrate that mimicking phosphorylation significantly reduces cryAB secretion via exosomes. Moreover, decreased colocalization of 3-SD YFP-cryAB with multivesicular endosome (MVE) and exosome marker, CD63 or Rab27, a small GTPase regulating exocytosis of MVEs, suggests that phosphorylation deters packaging of cryAB in vesicles bound for secretion as exosomes. Additionally, we found that preventing O-GlcNAcylation on cryAB also curtailed its colocalization with CD63 and Rab27 resulting in reduced exosomal secretion. Thus, our study points to O-GlcNAcylation and lack of phosphorylation as being the selective processes involved in the packaging and secretion of cryAB via exosomes.

Inflammatory cytokines, interleukin-1 beta and tumor necrosis factor-alpha, upregulated in glioblastoma multiforme, raise the levels of CRYAB in exosomes secreted by U373 glioma cells.

In the brain, levels of inflammatory cytokines, interleukin-1 beta (IL-1ß) and tumor necrosis factor-alpha (TNF-α), are elevated under traumatic brain injury, neuroinflammatory conditions and glioblastoma multiforme (GBM). In GBM, the levels of small heat shock protein, CRYAB (HspB5) are also reported to be elevated, where it has been shown to exert anti-apoptotic activity. Interestingly, CRYAB is secreted via exosomes by various cells. In order to understand the relation between inflammatory cytokines and CRYAB, U373 glioma cells, were stimulated with proinflammatory cytokines, IL-1ß and TNF-α, and their effect on CRYAB levels in cells and secreted exosomes was studied. Our results show that U373 cells produce and secrete CRYAB via exosomes and that stimulation with IL-1ß and TNF-α significantly increase the levels of CRYAB in not only the cells but also in the secreted exosomes. In addition, cytokine stimulation of U373 cells brings about changes in the secreted exosomal proteome, many of which are involved in cancer progression.

Mutants of human αB-crystallin cause enhanced protein aggregation and apoptosis in mammalian cells: influence of co-expression of HspB1.

Mutations of human αB-crystallin cause congenital cataract and cardio-myopathy by protein aggregation and cell death. How mutations of αB-crystallin become pathogenic is poorly understood. To better understand the cellular events related to protein aggregation and cell death, we transfected cataract and cardio-myopathy causing mutants, R11H, P20S, R56W, D109H, R120G, D140N, G154S, R157H and A171T in HeLa cells and assessed protein aggregation and apoptosis by laser scanning confocal microspy (LSCM) and flow cytometry. Cells individually transfected with the mutants, D109H, R120G, D140N and R157H significantly showed more aggregates. Cells overexpressed with HspB1 (Hsp27) significantly sequestered aggregates in all mutants and suppressed apoptosis in mutants, P20S, D109H and A171T. Significant increases of apoptotic cells as stained with Annexin V were observed in mutants, D109H and A171T transfected cells. Cells positive for active caspase-3 was increased in the mutant, D109H. Thus the previously recognized anti-apoptotic functions of αB-crystallin were compromised in these mutants.

Quaternary structural parameters of the congenital cataract causing mutants of αA-crystallin.

Pediatric cataract of the congenital type is the most common form of childhood blindness and it is clinically and genetically heterogeneous. Mutations in 22 different genes have been identified to be associated with congenital cataracts, and among them, eight mutants belong to αA-crystallin. To explain how mutations in αA-crystallin lead to the development of cataract, quaternary structural parameters, and chaperone function have been investigated in αA-wt and in the following mutants: R12C, R21L, R21W, R49C, R54C, R116C, and R116H. Average molar mass, mass at the RI peak, mass across the peak, hydrodynamic radius (R(h)), and polydispersity index (PDI) were determined by dynamic light-scattering measurements. The average molar mass and mass across the peak showed major increase in R116C and R116H, moderate increase in R12C, R21W, and R54C, and no increase in R21L and R49C as compared to αA-wt. PDI and R(h) values were significantly increased only in R116C and R116H. Significant secondary structural changes, as determined by CD measurements, were seen in R21W, R21L, R116C, and R116H, and tertiary structural changes were evident in R21W, R54C, R116C, and R116H. Non-reducing SDS-PAGE has shown the presence of dimers presumably formed by inter-polypeptide disulfide bonds. Chaperone activity, as measured with ADH as the target protein, appeared normal in R49C and R54C, while R12C, R21L, and R21W showed moderate loss and R116C and R116H showed significant loss. Although a specific change in the αA-crystallin behavior that is common to all the mutants was not evident, each mutant showed one or more perturbation as the end effect that leads to cataract.

Role of arginine-163 and the 163REEK166 motif in the oligomerization of truncated alpha A-crystallins.

To gain insight into the mechanism by which Arg-163 influences oligomerization of alphaA-crystallin, we prepared a series of truncated alphaA-crystallins with or without mutation of the Arg-163 residue. Expression of the proteins was achieved in Escherichia coli BL21 (DE3) pLysS cells, and alphaA-crystallin was purified by size-exclusion chromatography. Molecular mass was determined by molecular sieve HPLC, chaperone activity was assayed with alcohol dehydrogenase as the target protein, and structural changes were ascertained by circular dichroism (CD) measurements. With an increasing number of residues deleted, there was about a 3% decrease in oligomeric size per residue, until 10 residues were deleted. When 11 residues, including Arg-163, were deleted, the oligomeric size decreased 85%. Mutation of Arg-163 to Gly (R163G) did not affect the molecular mass in the full-length alphaA-crystallin. However, R163G mutants of all the truncated alphaA-crystallins showed a decrease in oligomeric size, those lacking 8, 9, and 10 residues showing 60-80% decrease and those lacking 5, 6, and 7 residues showing only a 7-14% decrease as compared to the corresponding truncated alphaA-crystallin. These data suggest that R163, E164, E165, and K166 in the REEK motif are also relevant to alphaA-crystallin oligomerization. The molecular masses of alphaA1-163 and alphaA1-163 (R163K) were nearly the same, which suggests that the role of Arg-163 is to provide a positive charge for intersubunit electrostatic interactions in the C-terminal domain. In alphaA1-162 (S162R), recovery of the molecular mass to the level in alphaA1-163 has not occurred; this shows that the actual position of R163 is important.

Enhanced C-terminal truncation of alphaA- and alphaB-crystallins in diabetic lenses.

PURPOSE: To investigate the influence of diabetes on the cleavage of C-terminal amino acid residues of alphaA- and alphaB-crystallins in human and rat lenses. METHODS: The human lenses were diabetic or age-matched control lenses from donors 57, 59, 69, and 72 years of age. Lenses were also obtained from streptozotocin-induced diabetic rats. Individual lens crystallins in water-soluble fractions were separated by gel-permeation chromatography. The high (alphaH)- and low (alphaL)-molecular-weight fractions were analyzed by electrospray ionization mass spectrometry. RESULTS: A typical mass spectrum of alphaA-crystallin from human lenses showed intact unmodified alphaA-crystallin, truncated alphaA(1-172), and monophosphorylated alphaA-crystallin. Diabetic lenses showed nearly twofold higher levels of alphaA(1-172) than did the control lenses. Also, the alphaH fraction consistently showed significantly higher levels of alphaA(1-172) than the alphaL fraction. Human alphaB-crystallin showed no evidence of C-terminal truncation. Rat alphaA-crystallin had five C-terminal-truncated components, most of which showed substantial increases in diabetes. Truncated alphaA(1-162) appeared only in the diabetic rat lenses, suggesting specific activation of m-calpain in diabetes. alphaB-crystallin had only one C-terminal-truncated component, alphaB(1-170), which also showed increased levels in diabetes. CONCLUSIONS: These data suggest that diabetic stress causes either enzymatic or nonenzymatic cleavage of peptide bonds between specific C-terminal amino acid residues. Such truncated alpha-crystallins appear to contribute to an increased level of the alphaH fraction generally present in diabetic lenses. Loss of alphaA-crystallin chaperone activity seems to be related to truncation of the C-terminal amino acid residues.

FoxO3a Serves as a Biomarker of Oxidative Stress in Human Lens Epithelial Cells under Conditions of Hyperglycemia.

BACKGROUND: Forkhead box 'O' transcription factors (FoxOs) are implicated in the pathogenesis of type2 diabetes and other metabolic diseases. Abnormal activity of FoxOs was reported in the glucose and insulin metabolism. Expression of FoxO proteins was reported in ocular tissues; however their function under hyperglycemic conditions was not examined. METHODS: Human lens epithelial cell line was used to study the function of FoxO proteins. Immunofluorescence, flow cytometry and Western blotting were employed to detect the FoxO proteins under the conditions of hyperglycemia. RESULTS: In this study we examined the role of FoxO3a in hyperglycemia-induced oxidative stress in human lens epithelial cells. FoxO3a protein expression was elevated in a dose- and time-dependent fashion after high glucose treatment. Anti-oxidant defense mechanisms of the lens epithelial cells were diminished as evidenced from loss of mitochondrial membrane integrity and lowered MnSOD after 72 h treatment with high glucose. Taken together, FoxO3a acts as a sensitive indicator of oxidative stress and cell homeostasis in human lens epithelial cells during diabetic conditions. CONCLUSION: FoxO3a is an early stress response protein to glucose toxicity in diabetic conditions.

Mutations in human αA-crystallin/sHSP affect subunit exchange interaction with αB-crystallin.

BACKGROUND: Mutation in αA-crystallin contributes to the development of congenital cataract in humans. Heterooligomerization of αA-crystallin and αB-crystallin is essential for maintaining transparency in the eye lens. The effect of congenital cataract causing mutants of αA-crystallin on subunit exchange and interaction with αB-crystallin is unknown. In the present study, interaction of the mutants of αA-crystallin with αB-crystallin was studied both in vitro and in situ by the fluorescence resonance energy transfer (FRET) technique. METHODOLOGY/PRINCIPAL FINDINGS: In vitro FRET technique was used to demonstrate the rates of subunit exchange of αB-wt with the following αA-crystallin mutants: R12C, R21L, R21W, R49C, R54C, and R116C. The subunit exchange rates (k values) of R21W and R116C with αB-wt decreased drastically as compared to αA-wt interacting with αB-wt. Moderately decreased k values were seen with R12C, R49C and R54C while R21L showed nearly normal k value. The interaction of αA- mutants with αB-wt was also assessed by in situ FRET. YFP-tagged αA mutants were co-expressed with CFP-tagged αB-wt in HeLa cells and the spectral signals were captured with a confocal microscope before and after acceptor laser photobleaching. The interaction of R21W and R116C with αB-wt was decreased nearly 50% as compared to αA-wt while the rest of the mutants showed slightly decreased interaction. Thus, there is good agreement between the in vitro and in situ FRET data. CONCLUSIONS/SIGNIFICANCE: Structural changes occurring in these mutants, as reported earlier, could be the underlying cause for the decreased interaction with αB may contribute to development of congenital cataract.

Congenital cataract causing mutants of αA-crystallin/sHSP form aggregates and aggresomes degraded through ubiquitin-proteasome pathway.

BACKGROUND: Mutations of human αA-crystallin cause congenital cataract by protein aggregation. How mutations of αA-crystallin cause disease pathogenesis through protein aggregation is not well understood. To better understand the cellular events leading to protein aggregation, we transfected cataract causing mutants, R12C, R21L, R21W, R49C, R54C, R116C and R116H, of human αA-crystallin in HeLa cells and examined the formation of intracellular protein aggregates and aggresomes by confocal microscopy. METHODOLOGY/PRINCIPAL FINDINGS: YFP-tagged human αA-wild-type (αA-wt) was sub-cloned and the mutants were generated by site-directed mutagenesis. The αA-wt and the mutants were individually transfected or co-transfected with CFP-tagged αA-wt or αB-wild-type (αB-wt) in HeLa cells. Overexpression of these mutants forms multiple small dispersed cytoplasmic aggregates as well as aggresomes. Co-expression of αB-wt with these mutants significantly inhibited protein aggregates where as co-expression with αA-wt enhanced protein aggregates which seems to be due to co-aggregation of the mutants with αA-wt. Aggresomes were validated by double immunofluorescence by co-localization of γ-tubulin, a centrosome marker protein with αA-crystallin. Furthermore, increased ubiquitination was detected in R21W, R116C and R116H as assessed by western blot analyses. Immunostaining with an ubiquitin antibody revealed that ubiquitin inclusions in the perinuclear regions were evident only in R116C transfected cells. Pulse chase assay, after cycloheximide treatment, suggested that R116C degraded faster than the wild-type control. CONCLUSIONS/SIGNIFICANCE: Mutants of αA-crystallin form aggregates and aggresomes. Co-expression of αA-wt with the mutants increased aggregates and co-expression of αB-wt with the mutants significantly decreased the aggregates. The mutant, R116C protein degraded faster than wild-type control and increased ubiquitination was evident in R116C expressing cells.

Multiple aggregates and aggresomes of C-terminal truncated human αA-crystallins in mammalian cells and protection by αB-crystallin.

BACKGROUND: Cleavage of 11 (αA162), 5 (αA168) and 1 (αA172) residues from the C-terminus of αA-crystallin creates structurally and functionally different proteins. The formation of these post-translationally modified αA-crystallins is enhanced in diabetes. In the present study, the fate of the truncated αA-crystallins expressed in living mammalian cells in the presence and absence of native αA- or αB-crystallin has been studied by laser scanning confocal microscopy (LSM). METHODOLOGY/PRINCIPAL FINDINGS: YFP tagged αAwt, αA162, αA168 and αA172, were individually transfected or co-transfected with CFP tagged αAwt or αBwt, expressed in HeLa cells and studied by LSM. Difference in protein aggregation was not caused by different level of α-crystallin expression because Western blotting results showed nearly same level of expression of the various α-crystallins. The FRET-acceptor photo-bleaching protocol was followed to study in situ protein-protein interaction. αA172 interacted with αAwt and αBwt better than αA168 and αA162, interaction of αBwt being two-fold stronger than that of αAwt. Furthermore, aggresomes were detected in cells individually expressing αA162 and αA168 constructs and co-expression with αBwt significantly sequestered the aggresomes. There was no sequestration of aggresomes with αAwt co-expression with the truncated constructs, αA162 and αA168. Double immunocytochemistry technique was used for co-localization of γ-tubulin with αA-crystallin to demonstrate the perinuclear aggregates were aggresomes. CONCLUSIONS/SIGNIFICANCE: αA172 showed the strongest interaction with both αAwt and αBwt. Native αB-crystallin provided protection to partially unfolded truncated αA-crystallins whereas native αA-crystallin did not. Aggresomes were detected in cells expressing αA162 and αA168 and αBwt co-expression with these constructs diminished the aggresome formation. Co-localization of γ-tubulin in perinuclear aggregates validates for aggresomes.

Interaction of C-terminal truncated human alphaA-crystallins with target proteins.

BACKGROUND: Significant portion of alphaA-crystallin in human lenses exists as C-terminal residues cleaved at residues 172, 168, and 162. Chaperone activity, determined with alcohol dehydrogenase (ADH) and betaL-crystallin as target proteins, was increased in alphaA(1-172) and decreased in alphaA(1-168) and alphaA(1-162). The purpose of this study was to show whether the absence of the C-terminal residues influences protein-protein interactions with target proteins. METHODOLOGY/PRINCIPAL FINDINGS: Our hypothesis is that the chaperone-target protein binding kinetics, otherwise termed subunit exchange rates, are expected to reflect the changes in chaperone activity. To study this, we have relied on fluorescence resonance energy transfer (FRET) utilizing amine specific and cysteine specific fluorescent probes. The subunit exchange rate (k) for ADH and alphaA(1-172) was nearly the same as that of ADH and alphaA-wt, alphaA(1-168) had lower and alphaA(1-162) had the lowest k values. When betaL-crystallin was used as the target protein, alphaA(1-172) had slightly higher k value than alphaA-wt and alphaA(1-168) and alphaA(1-162) had lower k values. As expected from earlier studies, the chaperone activity of alphaA(1-172) was slightly better than that of alphaA-wt, the chaperone activity of alphaA(1-168) was similar to that of alphaA-wt and alphaA(1-162) had substantially decreased chaperone activity. CONCLUSIONS/SIGNIFICANCE: Cleavage of eleven C-terminal residues including Arg-163 and the C-terminal flexible arm significantly affects the interaction with target proteins. The predominantly hydrophilic flexible arm appears to be needed to keep the chaperone-target protein complex soluble.

C-Terminal truncation affects subunit exchange of human alphaA-crystallin with alphaB-crystallin.

In human lenses, C-terminal cleavage of alphaA-crystallin at residues 172,168, and 162 have been reported. The effect of C-terminal truncation of alphaA-crystallin on subunit exchange and heterooligomer formation with alphaB-crystallin and homooligomer formation with native alphaA-crystallin is not known. We have conducted fluorescence resonance energy transfer studies which have shown that the rates of subunit exchange of alphaA(1-172 )and alphaA(1-168 )with alphaB-wt were two-fold lower than for alphaA-wt interacting with alphaB-wt. The subunit exchange rate between alphaA(1-162) and alphaB-wt was six-fold lower. These data suggest that cleavage of the C-terminal residues could significantly affect heterooligomerization. On the other hand, the subunit exchange rates between alphaA-wt and the truncated alphaA-crystallins were either unchanged or only slightly decreased, which suggest that homooligomerization may not be significantly influenced by C-terminal truncation. The main conclusion from this study is that cleavage of C-terminal residues of alphaA-crystallin including the nine residues of the flexible tail is expected to significantly affect the formation of heteroaggregates. Reconstitution experiments showed that the presence of an intact C-terminus is essential for the formation of fully integrated heteroaggregates with equal proportion of alphaA and alphaB subunits.

Reversal of chaperone activity loss of glycated alphaA-crystallin by a crosslink breaker.

The chaperone function of alpha-crystallin is significantly affected in diabetes. Increased formation of advanced glycation end products (AGEs) is the likely cause. This study was aimed to investigate the effect of AGE crosslinks on the chaperone activity of alpha-crystallin and to show the effect of an AGEs crosslink breaker, phenacyl-4,5-dimethylthiazolium bromide (DMPTB). Recombinant alphaA-crystallin was prepared by expressing it in Escherichia coli and purified by size exclusion chromatography. Glycation of alphaA-crystallin was performed with 1-100 mM glucose-6-phosphate (G6P) as the glycating agent for a period of 1-15 days. To break AGE crosslinks, pre-glycated alphaA-crystallin was treated with 0.1-20 mM DMPTB for 3 days. Excess G6P and DMPTB were removed by gel filtration before performing additional experiments. AGEs and crosslinked proteins were estimated by measuring non-tryptophan fluorescence and by SDS-PAGE. Chaperone activity was determined with alcohol dehydrogenase as the target protein. With increasing duration of glycation and G6P concentration, chaperone activity of alpha-crystallin decreased. When pre-glycated alphaA-crystallin was treated with 5-20 mM DMPTB, a DMPTB concentration-dependent recovery of chaperone activity was seen. Lower concentrations, 0.1, 0.5, and 1.0 mM, of DMPTB also showed significant recovery of the chaperone activity. SDS-PAGE analysis after DMPTB treatment showed 40% decrease in crosslinked proteins and fluorescence scan indicated 30% decrease in AGEs. DMPTB is expected to regain alpha-crystallin chaperone activity and provide structural stability to other eye lens proteins that are in aggregation mode which emphasizes the clinical importance of the present finding.

Role of the specifically targeted lysine residues in the glycation dependent loss of chaperone activity of alpha A- and alpha B-crystallins.

Earlier studies have shown significant loss of chaperone activity in alpha-crystallin from diabetic lenses. In vitro glycation studies have suggested that glycation of alpha-crystallin could be the major cause of chaperone activity loss. The following lysine (K) residues in alpha-crystallin have been identified as the major glycation sites: K11, K78, and K166 in alpha A-crystallin and K90, K92, and K166 in alpha B-crystallin. The present study was aimed to assess the contribution of each of the above glycation site in the overall glycation and loss of chaperone activity by mutating them to threonine followed by in vitro glycation with fructose. Level of glycated protein (GP) was determined by phenylboronate affinity chromatography, advanced glycation end products (AGEs) by direct ELISA using anti-AGE polyclonal antibody, and chaperone activity by using alcohol dehydrogenase as the target protein. K11T, K78, and K166T mutants of alpha A showed 33, 17, and 27% decrease in GP and 32, 18, and 21% decrease in AGEs, respectively, as compared to alpha A-wt. Likewise, K90T, K92T, K90T/K92T, and K166T mutants of alpha B showed 18, 21, 29, and 12% decrease in GP and 22, 24, 32, and 16% decrease in AGEs, respectively. Chaperone activity also showed concomitant increase with decreasing glycation and AGEs formation. alpha A-K11T and alpha B-K90T/K92T mutants showed the largest decrease in glycation and increase in chaperone activity.

Cleavage of the C-terminal serine of human alphaA-crystallin produces alphaA1-172 with increased chaperone activity and oligomeric size.

This study aimed to study the oligomeric size, structure, hydrodynamic properties, and chaperone function of the C-terminally truncated human alphaA-crystallin mutants with special emphasis on alphaA1-172 which is the cleavage product of the Ser172-Ser173 bond, unique to human lenses and constituting a major part of alphaA-crystallin. Various truncated forms of human alphaA-crystallins were prepared by site-directed mutagenesis. The proteins were expressed in Escherichia coli BL21(DE3) pLysS cells and purified by size exclusion column chromatography. Molecular masses and the other hydrodynamic properties were determined by dynamic light scattering measurements. The secondary and tertiary structural changes were assessed by far- and near-UV CD spectra measurements, respectively. Chaperone activity was determined by using ADH, insulin, and betaL-crystallin as the target proteins. alphaAlpha1-172 exhibited a significant increase in oligomeric size, i.e., 866 kDa by light scattering measurements as compared to 702 kDa in alphaA-wt. alphaAlpha1-172 and alphaA-wt had similar secondary structure, but the former exhibited slightly altered tertiary structure. The most interesting observation was that alphaAlpha1-172 behaved as a 28-46% better chaperone than alphaA-wt. The oligomeric size and structure of alphaAlpha1-168 were similar to those of alphaA-wt, while the chaperone activity was decreased by 12-23%. alphaAlpha1-162, on the other hand, had an oligomeric size of 400 kDa, a decrease in chaperone activity of 80-100%, and significantly altered secondary and tertiary structures. The data show that the overall chaperone function of alphaA-crystallin will be significantly improved by the presence of the major truncated product alphaAlpha1-172. This will be beneficial to the lens undergoing oxidative stress. Since alphaAlpha1-168 and alphaAlpha1-162 are present only in small amounts, their effect would be minimal.

Effect of oxidation of alphaA- and alphaB-crystallins on their structure, oligomerization and chaperone function.

The purpose of this study was to investigate the effect of metal-catalyzed oxidation by H(2)O(2) on the structure, oligomerization, and chaperone function of alphaA- and alphaB-crystallins. Recombinant alphaA-and alphaB-crystallins were prepared by expressing them in E. coli and purifying by size-exclusion chromatography. They were incubated with 1.5 mM H(2)O(2) and 0.1 mM FeCl(3) at 37 ( composite function)C for 24 hrs and the reaction was stopped by adding catalase. Structural changes due to oxidation were ascertained by circular dichroism (CD) measurements and chaperone activity was assayed with alcohol dehydrogenase (ADH) and insulin as target proteins. The oligomeric nature of the oxidized proteins was assessed by molecular sieve HPLC. The secondary structure of the oxidized alphaA- and alphaB-crystallins has been substantially altered due to significant increase in random coils, in addition to decrease in beta-sheet or alpha-helix contents. The tertiary structure also showed significant changes indicative of different mode of folding of the secondary structural elements. Chaperone function was significantly compromised as supported by nearly 50% loss in chaperone activity. Oxidation also resulted in the formation of higher molecular weight (HMW) proteins as well as lower molecular weight (LMW) proteins. Thus, oxidation leads to disintegration of the oligomeric structure of alphaA- and alphaB-crystallins. Chaperone activity of the HMW fraction is normal whereas the LMW fraction lacks any chaperone activity. So, it appears that the formation of the LMW proteins is the primary cause of the chaperone activity loss due to oxidation.

Influence of the C-terminal residues on oligomerization of alpha A-crystallin.

Earlier studies have shown that the chaperone activity of alpha-crystallin is significantly affected in diabetic rat and human lenses. Subsequently, mass spectrometric analysis showed diabetic lenses having high levels of the alphaA-crystallins in which different numbers of C-terminal residues were deleted. The present study was aimed to show whether cleavage of these residues influences protein structure, oligomerization, and chaperone function. For generation of various mutants, a stop codon was introduced at the positions of interest, proteins were expressed in BL21(DE3)pLys S E. coli, and the truncated alphaA-crystallins were purified by size-exclusion chromatography. The molecular masses, as determined by molecular sieve HPLC, of mutants with deletions of 1, 5, and 10 C-terminal residues (group-1) were 519-602 kDa, and those of mutants with deletions of 11, 16, and 22 C-terminal residues (group-2) were 148-152 kDa, as compared to 607 kDa for alphaA-wild type. On the basis of circular dichroism measurements, the alpha helix content was 2-fold higher and the tertiary structure was significantly altered in the group-2 mutants. Chaperoning abilities, as determined by the ADH assay and the betaL-crystallin heat denaturation assay, of the group-1 mutants, with the exception of alphaA(1-163), were slightly improved or unchanged, that of alphaA(1-163) was moderately affected, and those of the group-2 mutants were severely affected. Most strikingly, cleavage of 11 C-terminal residues including Arg-163 showed a substantial decrease in oligomeric size and chaperone function and significant changes in protein structure whereas cleavage of 10 residues had either a small effect or no effect at all. This points to an important role for the C-terminal extension, Arg-163 in particular, and no significant role for the C-terminal flexible tail in the oligomer assembly of alphaA-crystallin.

Thermally induced disintegration of the oligomeric structure of alphaB-crystallin mutant F28S is associated with diminished chaperone activity.

alphaB-crystallin, a member of the small heat-shock protein (hsp) family of proteins, is able to function as a molecular chaperone by protecting other proteins from stress-induced aggregation by recognizing and binding to partially unfolded species of damaged proteins. The present work has investigated the role of phenylalanine-28 (F28) of the 22RLFDQFF28 region of alphaB-crystallin in maintaining chaperone function and oligomeric structure under physiological condition and under thermal stress. Bovine alphaB-crystallin was cloned for the first time and the cDNA sequence revealed greater than 90% homology to that of human, rat and mouse alphaB-crystallins. F28 was mutated to a serine followed by expression of the mutant F28S and the wild-type alphaB (alphaB-wt) in E. coli and subsequent purification of the protein by size-exclusion chromatography. Secondary and tertiary structure analyses showed some structural changes in the mutant. Chaperone activity and oligomeric size of the mutant was unchanged at 37 degrees C whereas at 58 degrees C the chaperone activity was significantly decreased and the oligomeric size ranged from low molecular weight to high molecular weight showing disintegration of the oligomeric structure. The data support the idea that the participation of large oligomeric structure rather than smaller units is required to have optimal chaperone activity and the hydrophobic F28 residue is needed for maintaining the native oligomeric structure under thermal stress.

The alphaA-crystallin R116C mutant has a higher affinity for forming heteroaggregates with alphaB-crystallin.

An autosomal dominant congenital cataract in humans is associated with mutation of Arg-116 to Cys in alphaA-crystallin (alphaA-R116C). The chaperone activity and biophysical properties of reconstituted alpha-crystallin from different proportions of wild-type alphaB-crystallin (alphaB-wt) and alphaA-R116C-crystallin were studied by gel permeation chromatography, SDS-polyacrylamide gel electrophoresis, and fluorescence and circular dichroism spectroscopy and compared with those of reconstituted alpha-crystallin from alphaB-wt and wild-type alphaA-crystallin (alphaA-wt). The reconstituted alpha-crystallin containing alphaA-R116C and alphaB-wt had a higher molecular mass, a higher thermal sensitivity to exposition of Trp side chains, fewer available hydrophobic surfaces, and lower chaperone activity than the alpha-crystallin containing alphaA-wt and alphaB-wt. The secondary structure exhibited very small changes, whereas the tertiary structure was distinctly different for alpha-crystallin formed from alphaA-R116C and alphaB-wt. Most importantly, subunit exchange studies by fluorescence resonance energy transfer showed that alphaA-R116C forms heteroaggregates faster than alphaA-wt with alphaB-wt, and the reconstituted alpha-crystallins were true heteroaggregates of two interacting subunits. These findings suggest that the molecular basis for the congenital cataract with the alphaA-R116C mutation is the formation of highly oligomerized heteroaggregates of alpha-crystallin with modified structure. However, contrary to the earlier conclusions based on the studies of homoaggregates, the loss in chaperone activity of the heteroaggregates having alphaA-R116C does not appear to be large enough to become the main factor in initiating cataract development in the affected individuals.

alpha-Crystallin chaperone function in diabetic rat and human lenses.

This study focussed on the effect of diabetes on the chaperone function of alpha-crystallin. The authors relied on diabetic rats with a wide range of plasma glucose levels and non-diabetic control rats to establish a possible relationship between severity of diabetes and alpha-crystallin chaperone activity. In addition, 52-56 and 63-69 year-old diabetic and non-diabetic human lenses were used to show whether diabetes affects alpha-crystallin chaperone activity in human lenses. Correlation between plasma glucose levels and loss of chaperone activity of the alphaL-crystallin fraction in diabetic rats indicated good correlation. The glycemic threshold, reported before for cataract development in diabetic rats, seems to be valid for the chaperone activity loss as well. Analysis of the human lens alphaL-crystallin showed lower chaperone activity in all the diabetic lenses than in the age-matched control lenses. In the 63-69 age group, the loss in chaperone activity due to diabetes was significantly larger than in the 52-56 age group suggesting a dominant effect of duration of diabetes.