Structural and Mechanical Hierarchies in the α-Crystallin Domain Dimer of the Hyperthermophilic Small Heat Shock Protein Hsp16.5

In biological systems, proteins rarely act as isolated monomers. Association to dimers or higher oligomers is a commonly observed phenomenon. As an example, small heat shock proteins form spherical homo-oligomers of mostly 24 subunits, with the dimeric α-crystallin domain as the basic structural unit. The structural hierarchy of this complex is key to its function as a molecular chaperone. In this article, we analyze the folding and association of the basic building block, the α-crystallin domain dimer, from the hyperthermophilic archaeon Methanocaldococcus jannaschii Hsp16.5 in detail. Equilibrium denaturation experiments reveal that the α-crystallin domain dimer is highly stable against chemical denaturation. In these experiments, protein dissociation and unfolding appear to follow an “all-or-none” mechanism with no intermediate monomeric species populated. When the mechanical stability was determined by single-molecule force spectroscopy, we found that the α-crystallin domain dimer resists high forces when pulled at its termini. In contrast to bulk denaturation, stable monomeric unfolding intermediates could be directly observed in the mechanical unfolding traces after the α-crystallin domain dimer had been dissociated by force. Our results imply that for this hyperthermophilic member of the small heat shock protein family, assembly of the spherical 24mer starts from folded monomers, which readily associate to the dimeric structure required for assembly of the higher oligomer.     

Functional Elements in Molecular Chaperone α-Crystallin: Identification of Binding Sites in αB-Crystallin

α-Crystallin, the predominant eye lens protein with sequence homology to small heat shock proteins, acts like a molecular chaperone by suppressing the aggregation of damaged crystallins and proteins. To gain an insight into the amino acid sequences in α-crystallin involved in chaperone-like function, we used a cleavable, fluorescent, photoactive, crosslinking agent, sulfosuccinimidyl-2(7-azido-4-methylcoumarin-3-acetamido)-ethyl-1,3′ dithiopropionate (SAED), to derivatize yeast alcohol dehydrogenase (ADH) and allowed it to complex with bovine α-crystallin at 48°C. The complex was photolyzed and reduced with DTT and the subunits of α-crystallin, αA- and αB-, were separated. Fluorescence analysis showed that both αA- and αB-crystallins interacted with ADH during chaperone-like function. Tryptic digestion, amino acid sequencing, and mass spectral analysis of αB-crystallin revealed that APSWIDTGLSEMR (57-69) and VLGDVIEVHGKHEER (93-107) sequences were involved in binding with ADH.     

Regions Outside the α-Crystallin Domain of the Small Heat Shock Protein Hsp26 Are Required for Its Dimerization

Small heat shock proteins (sHsps) are a ubiquitous family of molecular chaperones. They form homo-oligomers, composed of mostly 24 subunits. The immunoglobulin-like α-crystallin domain, which is flanked by N- and C-terminal extensions, is the most conserved element in sHsps. It is assumed to be the dimeric building block from which the sHsp oligomers are assembled.Hsp26 from Saccharomyces cerevisiae is a well-characterized member of this family. With a view to study the structural stability and oligomerization properties of its α-crystallin domain, we produced a series of α-crystallin domain constructs. We show that a minimal α-crystallin domain can, against common belief, be monomeric and stably folded. Elongating either the N- or the C-terminus of this minimal α-crystallin domain with the authentic extensions leads to the formation of dimeric species. In the case of N-terminal extensions, their population is dependent on the presence of the complete so-called Hsp26 “middle domain”. For the C-terminal extensions, the presence of the conserved IXI motif of sHsps is necessary and sufficient to induce dimerization, which can be inhibited by increasing ionic strength. Dimerization does not induce major changes in secondary structure of the Hsp26 α-crystallin domain. A thermodynamic analysis of the monomeric and dimeric constructs revealed that dimers are not significantly stabilized against thermal and chemical denaturation in comparison to monomers, supporting our notion that dimerization is not a prerequisite for the formation of a well-folded Hsp26 α-crystallin domain.     

Association Properties and Unfolding of a βγ-Crystallin Domain of a Vibrio-Specific Protein

The βγ-crystallin superfamily possesses a large number of versatile members, of which only a few members other than lens βγ-crystallins have been studied. Understanding the non-crystallin functions as well as origin of crystallin-like properties of such proteins is possible by exploring novel members from diverse sources. We describe a novel βγ-crystallin domain with S-type (Spherulin 3a type) Greek key motifs in protein vibrillin from a pathogenic bacterium Vibrio cholerae. This domain is a part of a large Vibrio-specific protein prevalent in Vibrio species (found in at least fourteen different strains sequenced so far). The domain contains two canonical N/D-N/D-X-X-S/T-S Ca²⁺-binding motifs, and bind Ca²⁺. Unlike spherulin 3a and other microbial homologues studied so far, βγ-crystallin domain of vibrillin self-associates forming oligomers of various sizes including dimers. The fractionated dimers readily form octamers in concentration-dependent manner, suggesting an association between these two major forms. The domain associates/dissociates forming dimers at the cost of monomeric populations in the presence of Ca²⁺. No such effect of Ca²⁺ has been observed in oligomeric species. The equilibrium unfolding of both forms follows a similar pattern, with the formation of an unfolding intermediate at sub-molar concentrations of denaturant. These properties exhibited by this βγ-crystallin domain are not shown by any other domain studied so far, demonstrating the diversity in domain properties.     

Evaluation of Hydrophobicity Versus Chaperonelike Activity of Bovine αA- and αB-Crystallin

Calf lens αA-crystallin isolated by reversed-phase HPLC demonstrates a slightly more hydrophobic profile than αB-crystallin. Fluorescent probes in addition to bis-ANS, like cis-parinaric acid (PA) and pyrene, show higher quantum yields or Ham ratios when bound to αA-crystallin than to αB-crystallin at room temperature. Bis-ANS binding to both αA- and αB-crystallin decreases with increase in temperature. At room temperature, the chaperone-like activity of αA-crystallin is lower than that of αB-crystallin whereas at higher temperatures, αA-crystallin shows significantly higher protection against aggregation of substrate proteins compared to αB-crystallin. Therefore, calf lens αA-crystallin is more hydrophobic than αB-crystallin and chaperone-like activity of α-crystallin subunits is not quantitatively related to their hydrophobicity.     

In Vivo Substrates of the Lens Molecular Chaperones αA-Crystallin and αB-Crystallin

αA-crystallin and αB-crystallin are members of the small heat shock protein family and function as molecular chaperones and major lens structural proteins. Although numerous studies have examined their chaperone-like activities in vitro, little is known about the proteins they protect in vivo. To elucidate the relationships between chaperone function, substrate binding, and human cataract formation, we used proteomic and mass spectrometric methods to analyze the effect of mutations associated with hereditary human cataract formation on protein abundance in αA-R49C and αB-R120G knock-in mutant lenses. Compared with age-matched wild type lenses, 2-day-old αA-R49C heterozygous lenses demonstrated the following: increased crosslinking (15-fold) and degradation (2.6-fold) of αA-crystallin; increased association between αA-crystallin and filensin, actin, or creatine kinase B; increased acidification of βB1-crystallin; increased levels of grifin; and an association between βA3/A1-crystallin and αA-crystallin. Homozygous αA-R49C mutant lenses exhibited increased associations between αA-crystallin and βB3-, βA4-, βA2-crystallins, and grifin, whereas levels of βB1-crystallin, gelsolin, and calpain 3 decreased. The amount of degraded glutamate dehydrogenase, α-enolase, and cytochrome c increased more than 50-fold in homozygous αA-R49C mutant lenses. In αB-R120G mouse lenses, our analyses identified decreased abundance of phosphoglycerate mutase, several β- and γ-crystallins, and degradation of αA- and αB-crystallin early in cataract development. Changes in the abundance of hemoglobin and histones with the loss of normal α-crystallin chaperone function suggest that these proteins also play important roles in the biochemical mechanisms of hereditary cataracts. Together, these studies offer a novel insight into the putative in vivo substrates of αA- and αB-crystallin.     

Open-Channel Structures of the Human Glycine Receptor α1 Full-Length Transmembrane Domain

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Localization and Expression of Hsp27 and αB-Crystallin in Rat Primary Myocardial Cells during Heat Stress In Vitro

Neonatal rat primary myocardial cells were subjected to heat stress in vitro, as a model for investigating the distribution and expression of Hsp27 and αB-crystallin. After exposure to heat stress at 42°C for different durations, the activities of enzymes expressed during cell damage increased in the supernatant of the heat-stressed myocardial cells from 10 min, and the pathological lesions were characterized by karyopyknosis and acute degeneration. Thus, cell damage was induced at the onset of heat stress. Immunofluorescence analysis showed stronger positive signals for both Hsp27 and αB-crystallin from 10 min to 240 min of exposure compared to the control cells. According to the Western blotting results, during the 480 min of heat stress, no significant variation was found in Hsp27 and αB-crystallin expression; however, significant differences were found in the induction of their corresponding mRNAs. The expression of these small heat shock proteins (sHsps) was probably delayed or overtaxed due to the rapid consumption of sHsps in myocardial cells at the onset of heat stress. Our findings indicate that Hsp27 and αB-crystallin do play a role in the response of cardiac cells to heat stress, but the details of their function remain to be investigated.     

Effect of Trehalose on Oligomeric State and Anti-Aggregation Activity of αB-Crystallin

Biochemistry (Moscow) - αB-Crystallin (αB-Cr), one of the main crystalline lens proteins, along with other crystallins maintains lens transparency suppressing protein aggregation and thus...     

Crystal Structures of a CTXφ pIII Domain Unbound and in Complex with a Vibrio cholerae TolA Domain Reveal Novel Interaction Interfaces

Vibrio cholerae colonize the small intestine where they secrete cholera toxin, an ADP-ribosylating enzyme that is responsible for the voluminous diarrhea characteristic of cholera disease. The genes encoding cholera toxin are located on the genome of the filamentous bacteriophage, CTXφ, that integrates as a prophage into the V. cholerae chromosome. CTXφ infection of V. cholerae requires the toxin-coregulated pilus and the periplasmic protein TolA. This infection process parallels that of Escherichia coli infection by the Ff family of filamentous coliphage. Here we demonstrate a direct interaction between the N-terminal domain of the CTXφ minor coat protein pIII (pIII-N1) and the C-terminal domain of TolA (TolA-C) and present x-ray crystal structures of pIII-N1 alone and in complex with TolA-C. The structures of CTXφ pIII-N1 and V. cholerae TolA-C are similar to coliphage pIII-N1 and E. coli TolA-C, respectively, yet these proteins bind via a distinct interface that in E. coli TolA corresponds to a colicin binding site. Our data suggest that the TolA binding site on pIII-N1 of CTXφ is accessible in the native pIII protein. This contrasts with the Ff family phage, where the TolA binding site on pIII is blocked and requires a pilus-induced unfolding event to become exposed. We propose that CTXφ pIII accesses the periplasmic TolA through retraction of toxin-coregulated pilus, which brings the phage through the outer membrane pilus secretin channel. These data help to explain the process by which CTXφ converts a harmless marine microbe into a deadly human pathogen.     

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

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

Unfolding and Refolding of Bovine α-Crystallin in Urea and Its Chaperone Activity

We undertook an unfolding and refolding study of α_L-crystallin in presence of urea to explore the breakdown and formation of various levels of structure and to find out whether the breakdown of various levels of structure occurs simultaneously or in a hierarchal manner. We used various techniques such as circular dichroism, fluorescence spectroscopy, light scattering, polarization to determine the changes in secondary, tertiary, and quaternary structure. Unfolding and refolding occurred through a number of intermediates. The results showed that all levels of structure in α_L-crystallin collapsed or reformed simultaneously. The intermediates that occurred in the 2–4 M urea concentration range during unfolding and refolding differed from each other in terms of the polarity of the tryptophan environment. The ANS binding experiments revealed that refolded α_L-crystallin had higher number of hydrophobic pockets compared to native one. On the other hand, polarity of these pockets remained same as that of the native protein. Both light scattering and polarization measurements showed smaller oligomeric size of refolded α_L-crystallin. Thus, although the secondary structural changes were almost reversible, the tertiary and quaternary structural changes were not. The refolded α_L-crystallin had more exposed hydrophobic sites with increased binding affinity. The refolded form also showed higher chaperone activity than native one. Since the refolded form was smaller in oligomeric size, some buried hydrophobic sites were available. The higher chaperone activity of lower sized oligomer of α_L-crystallin again revealed that chaperone activity was dependent on hydrophobicity and not on oligomeric size.     

Crystal and molecular structures of substituted α-d-glucopyranosides

The crystal and molecular structures of methyl 2,4,6-tri-O-pivaloyl-α-d-glucopyranoside (1), methyl 4,6-O-(R)-benzylidene-2-O-pivaloyl-α-d-glucopyranoside (2), and methyl 4,6-O-(R)-benzylidene-2,3-di-O-pivaloyl-α-d-glucopyranoside (3) were determined by X-ray analysis. Crystals of 1 are orthorhombic, space group P2₁2₁2₁ with the unit cell a = 13.026(2), b = 16.832, c = 11.929(2) Å, Z = 4. Crystals of 2 are monoclinic, space group P2₁. The unit-cell parameters are a = 6.519(1), b = 14.664(4), c = 10.635(4) Å, β = 93.18(1)°, Z = 2. Crystals of 3 are orthorhombic, space group P2₁2₁2₁ with a = 10.006(3), b = 13.874(3), c = 18.527(5) Å, Z = 4. The structures were solved by MULTAN and refined by a full-matrix procedure to final values of R = 0.084 (1), 0.048 (2), and 0.069 (3). The pyranose ring in each compound adopts the ⁴C₁ conformation. The 1,3-dioxane rings in 2 and 3 show a chair conformation. The molecular packing in 1 is through the hydrogen bonds involving HO-3 and the 6-O-pivaloyl carbonyl group [HO-3 ⋯ O-9, 2.855(8) Å], which connect the molecules into a chain along

. The endocyclic oxygen atom is involved in an intermolecular hydrogen-bond with HO-3 [2.848(4) Å], joining molecules of 2 into the chains along

. There are no free hydroxyl groups in 3 and molecular packing reflects van der Waals interactions only.     

Characterization of O-Phosphohydroxyproline in Rat α-Crystallin A

Post-translational modifications have major importance for the structure and function of a multiplicity of proteins. Phosphorylation is a widespread phenomenon among eukaryotic proteins. Whereas O-phosphorylation on the side chains of serine, threonine, and tyrosine in proteins is well known and has been studied extensively, to our knowledge the endogenous phosphorylation of hydroxyproline has not previously been reported. In the present work, we provide evidence for the first time that O-phosphohydroxyproline (Hyp(P)) is a proteinogenic amino acid. To detect Hyp(P) in proteins we generated a Hyp(P)-specific polyclonal antibody. We could identify Hyp(P) in various proteins by Western blot analysis, and we characterized the sequence position of Hyp(P) in the protein α-crystallin A by electrospray ionization-tandem mass spectrometry. Our experiments clearly demonstrate hydroxylation and subsequent phosphorylation of a proline residue in α-crystallin A in the eye as well as in heart tissue of rat.     

Impact of Subunit Composition on the Uptake of α-Crystallin by Lens and Retina

Misfolded protein aggregation, including cataract, cause a significant amount of blindness worldwide. α-Crystallin is reported to bind misfolded proteins and prevent their aggregation. We hypothesize that supplementing retina and lens with α-crystallin may help to delay disease onset. The purpose of this study was to determine if αB-crystallin subunits containing a cell penetration peptide (gC-tagged αB-crystallin) facilitate the uptake of wild type αA-crystallin (WT-αA) in lens and retina. Recombinant human αB-crystallin was modified by the addition of a novel cell penetration peptide derived from the gC gene product of herpes simplex virus (gC-αB). Recombinant gC-αB and wild-type αA-crystallin (WT-αA) were purified from E. coli over-expression cultures. After Alexa-labeling of WT-αA, these proteins were mixed at ratios of 1:2, 1:5 and 1:10, respectively, and incubated at 37°C for 4 hours to allow for subunit exchange. Mixed oligomers were subsequently incubated with tissue culture cells or mouse organ cultures. Similarly, crystallin mixtures were injected into the vitreous of rat eyes. At various times after exposure, tissues were harvested and analyzed for protein uptake by confocal microscopy or flow cytometry. Chaperone-like activity assays were performed on α-crystallins ratios showing optimal uptake using chemically-induced or heat induced substrate aggregation assays. As determined by flow cytometry, a ratio of 1:5 for gC-αB to WT-αA was found to be optimal for uptake into retinal pigmented epithelial cells (ARPE-19). Chaperone-like activity assays demonstrated that hetero-oligomeric complex of gC-αB to WT-αA (in 1:5 ratio) retained protein aggregation protection. We observed a significant increase in protein uptake when optimized (gC-αB to WT-αA (1:5 ratio)) hetero-oligomers were used in mouse lens and retinal organ cultures. Increased levels of α-crystallin were found in lens and retina following intravitreal injection of homo- and hetero-oligomers in rats.     

Crystal Structures of the Free and Ligand-Bound FK1–FK2 Domain Segment of FKBP52 Reveal a Flexible Inter-Domain Hinge

The human Hsp90 co-chaperone FKBP52 belongs to the family of FK506-binding proteins, which act as peptidyl-prolyl isomerases. FKBP52 specifically enhances the signaling of steroid hormone receptors, modulates ion channels and regulates neuronal outgrowth dynamics. In turn, small-molecule ligands of FKBP52 have been suggested as potential neurotrophic or anti-prostate cancer agents. The usefulness of available ligands is however limited by a lack of selectivity. The immunophilin FKBP52 is composed of three domains, an FK506-binding domain with peptidyl-prolyl isomerase activity, an FKBP-like domain of unknown function and a TPR-clamp domain, which recognizes the C-terminal peptide of Hsp90 with high affinity. The herein reported crystal structures of FKBP52 reveal that the short linker connecting the FK506-binding domain and the FKBP-like domain acts as a flexible hinge. This enhanced flexibility and its modulation by phosphorylation might explain some of the functional antagonism between the closely related homologs FKBP51 and FKBP52. We further present two co-crystal structures of FKBP52 in complex with the prototypic ligand FK506 and a synthetic analog thereof. These structures revealed the molecular interactions in great detail, which enabled in-depth comparison with the corresponding complexes of the other cytosolic FKBPs, FKBP51 and FKBP12. The observed subtle differences provide crucial insights for the rational design of ligands with improved selectivity for FKBP52.     

Covalent α-Synuclein Dimers: Chemico-Physical and Aggregation Properties

The aggregation of α-synuclein into amyloid fibrils constitutes a key step in the onset of Parkinson''s disease. Amyloid fibrils of α-synuclein are the major component of Lewy bodies, histological hallmarks of the disease. Little is known about the mechanism of aggregation of α-synuclein. During this process, α-synuclein forms transient intermediates that are considered to be toxic species. The dimerization of α-synuclein could represent a rate-limiting step in the aggregation of the protein. Here, we analyzed four covalent dimers of α-synuclein, obtained by covalent link of the N-terms, C-terms, tandem cloning of two sequences and tandem juxtaposition in one protein of the 1–104 and 29–140 sequences. Their biophysical properties in solution were determined by CD, FT-IR and NMR spectroscopies. SDS-induced folding was also studied. The fibrils formation was analyzed by ThT and polarization fluorescence assays. Their morphology was investigated by TEM and AFM-based quantitative morphometric analysis. All dimers were found to be devoid of ordered secondary structure under physiological conditions and undergo α-helical transition upon interaction with SDS. All protein species are able to form amyloid-like fibrils. The reciprocal orientation of the α-synuclein monomers in the dimeric constructs affects the kinetics of the aggregation process and a scale of relative amyloidogenic propensity was determined. Structural investigations by FT IR spectroscopy, and proteolytic mapping of the fibril core did not evidence remarkable difference among the species, whereas morphological analyses showed that fibrils formed by dimers display a lower and diversified level of organization in comparison with α-synuclein fibrils. This study demonstrates that although α-synuclein dimerization does not imply the acquisition of a preferred conformation by the participating monomers, it can strongly affect the aggregation properties of the molecules. The results presented highlight a substantial role of the relative orientation of the individual monomer in the definition of the fibril higher structural levels.     

Cytoplasmic and Nuclear Anti-Apoptotic Roles of αB-Crystallin in Retinal Pigment Epithelial Cells

In addition to its well-characterized role in the lens, αB-crystallin performs other functions. Methylglyoxal (MGO) can alter the function of the basement membrane of retinal pigment epithelial (RPE) cells. Thus, if MGO is not efficiently detoxified, it can induce adverse reactions in RPE cells. In this study, we examined the mechanisms underlying the anti-apoptotic activity of αB-crystallin in the human retinal pigment epithelial cell line ARPE-19 following MGO treatment using various assays, including nuclear staining, flow cytometry, DNA electrophoresis, pulse field gel electrophoresis, western blot analysis, confocal microscopy and co-immunoprecipitation assays. To directly assess the role of phosphorylation of αB-crystallin, we used site-directed mutagenesis to convert relevant serine residues to alanine residues. Using these techniques, we demonstrated that MGO induces apoptosis in ARPE-19 cells. Silencing αB-crystallin sensitized ARPE-19 cells to MGO-induced apoptosis, indicating that αB-crystallin protects ARPE-19 cells from MGO-induced apoptosis. Furthermore, we found that αB-crystallin interacts with the caspase subtypes, caspase-2L, -2S, -3, -4, -7, -8, -9 and -12 in untreated control ARPE-19 cells and that MGO treatment caused the dissociation of these caspase subtypes from αB-crystallin; transfection of S19A, S45A or S59A mutants caused the depletion of αB-crystallin from the nuclei of untreated control RPE cells leading to the release of caspase subtypes. Additionally, transfection of these mutants enhanced MGO-induced apoptosis in ARPE-19 cells, indicating that phosphorylation of nuclear αB-crystallin on serine residues 19, 45 and 59 plays a pivotal role in preventing apoptosis in ARPE-19 cells. Taken together, these results suggest that αB-crystallin prevents caspase activation by physically interacting with caspase subtypes in the cytoplasm and nucleus, thereby protecting RPE cells from MGO-induced apoptosis.