Phe71 is essential for chaperone-like function in alpha A-crystallin

Experiments with mini-alphaA-crystallin (KFVIFLDVKHFSPEDLTVK) showed that Phe(71) in alphaA-crystallin could be essential for the chaperone-like action of the protein (Sharma, K. K., Kumar, R. S., Kumar, G. S., and Quinn, P. T. (2000) J. Biol. Chem. 275, 3767-3771). In the present study we replaced Phe(71) in rat alphaA-crystallin with Gly by site-directed mutagenesis and then compared the structural and functional properties of the mutant protein with the wild-type protein. There were no differences in molecular size or intrinsic tryptophan fluorescence between the proteins. However, 1,1'-bi(4-anilino)naphthalene-5,5'-disulfonic acid interaction indicated a higher hydrophobicity for the mutant protein. Both wild-type and mutant proteins displayed similar secondary structure during far UV CD experiments. Near UV CD signal showed a slight difference in the tertiary structure around the 285-295 region for the two proteins. The mutant protein was totally inactive in suppressing the aggregation of reduced insulin, heat-denatured citrate synthase, and alcohol dehydrogenase. However, a marginal suppression of beta(L)-crystallin aggregation was observed when mutant alphaA-crystallin was included. These results suggest that Phe(71) contributes to the chaperone-like action of alphaA-crystallin. Therefore we conclude that the 70-88-region in alphaA-crystallin, identified by us earlier, is the functional chaperone site in alphaA-crystallin.     

Structural and functional changes in the alpha A-crystallin R116C mutant in hereditary cataracts

alpha-Crystallin, the major protein component of vertebrate lenses, forms a large complex comprised of two homologous subunits, alphaA- and alphaB-crystallin. It has the ability to suppress stress-induced protein aggregation in vitro, bind saturably to lens plasma membranes, and aid in light refraction through short-range ordering. Recently, a missense mutation in alphaA-crystallin that changes arginine 116 to a cysteine residue (R116C) was genetically linked to one form of autosomal dominant congenital cataracts. This point mutation is reported to cause structural alterations at many levels as well as a 4-fold reduction in chaperone-like activity. To extend these findings, we examined the quaternary stability of the alphaA R116C mutant protein and its effect on chaperone-like activity, subunit exchange, and membrane association. Homocomplexes of mutant subunits become highly polydisperse following incubation at 37 degrees C, reflecting the likely in vivo distribution of the complexes. Chaperone-like activity of the alphaA R116C mutant is approximately 4-fold lower than wild type, whether measured before or after conversion to a polydisperse population with incubation. alphaA R116C complexes also have a 4-fold reduced ability to exchange subunits with wild-type complexes. Finally, membrane binding capacity measurements of mutant subunits showed a 10-fold increase over wild type. Our results, in conjunction with previous reports, suggest that the changes in complex polydispersity, the reduction of subunit exchange, and increased membrane binding capacity are all potential factors in the pathogenesis of alphaA R116C associated congenital cataracts.     

Effects of congenital cataract mutation R116H on αA-crystallin structure,function and stability

α-crystallin is a molecular chaperone that maintains the optical properties of the lens and delays the onset scattering caused by aging-related protein aggregation. In this research, we found that the missense mutation R116H resulted in an altered size distribution, impaired packing of the secondary structures and modified quaternary structure with great hydrophobic exposure. The mutant exhibited a substrate-dependent chaperone (aggregation–inhibition) or anti-chaperone (aggregation–promotion) effect. Equilibrium unfolding experiments indicated that the mutation stabilized an aggregation-prone intermediate which was not populated during the unfolding of the wild-type protein. The accumulation of this intermediate greatly promoted the formation of non-native large oligomers or aggregates during unfolding. These results suggested that both the aggregation of the mutant upon stress and co-deposition with the target proteins were likely to be responsible for the onset of cataract.     

The R116C mutation in alpha A-crystallin diminishes its protective ability against stress-induced lens epithelial cell apoptosis.

alphaA-crystallin is a small heat-shock protein expressed preferentially in the lens and is detected during the early stages of lens development. Recent work indicates that the expression of alphaA-crystallin enhances lens epithelial cell growth and resistance to stress conditions. Mutation of the arginine 116 residue to cysteine (R116C) in alphaA-crystallin has been associated with congenital cataracts in humans. However, the physiological consequences of this mutation have not been analyzed in lens epithelial cells. In the present study, we expressed wild type or R116C alphaA-crystallin in the human lens epithelial cell line HLE B-3. Immunofluorescence and confocal microscopy indicated that both wild type and R116C alphaA-crystallin were distributed mainly in the cytoplasm of lens epithelial cells. Size-exclusion chromatography indicated that the size of the alphaA-crystallin aggregate in lens epithelial cells increased from 500 to 600 kDa for the wild type protein to >2 MDa in the R116C mutant. When cells were exposed to physiological levels of UVA radiation, wild type alphaA-crystallin protected cells from apoptotic death as shown by annexin labeling and flow cytometric analysis, whereas the R116C mutant had a 4- to 10-fold lower protective ability. UVA-irradiated cells expressing the wild type protein had very low TUNEL (terminal deoxynucleotidyl transferase-mediated dUTP nick end labeling) staining, whereas cells expressing R116C mutant had a high level of TUNEL staining. F-actin was protected in UVA-treated cells expressing the wild type alphaA-crystallin but was either clumped around the apoptotic cells or was absent in apoptotic cells in cultures expressing the R116C mutant. Structural changes caused by the R116C mutation could be responsible for the reduced ability of the mutant to protect cells from stress. Our study shows that comparing the stress-induced apoptotic cell death is an effective way to compare the protective abilities of wild type and mutant alphaA-crystallin. We propose that the diminished protective ability of the R116C mutant in lens epithelial cells may contribute to the pathogenesis of cataract.     

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.     

A positive charge preservation at position 116 of alpha A-crystallin is critical for its structural and functional integrity

An autosomal dominant congenital cataract associated with a missense mutation, Arg-116 to Cys (R116C), in the coding sequence of human alphaA-crystallin has been reported. Subsequent study of this mutant, generated by site-directed mutagenesis, showed significant changes in secondary and tertiary structures, partial loss of chaperone activity, and substantially increased oligomeric size. The study presented here aims to show whether these changes are due to the loss of a positive charge at this position or due to the presence of an extra Cys. To show this, Arg-116 in alphaA-crystallin was mutated to Lys (R116K), Cys (R116C), Gly (R116G), and Asp (R116D) and expressed in Escherichia coli cells. The wild-type (alphaA-wt) and mutant proteins were purified by size exclusion chromatography and characterized by measurements of circular dichroism, intrinsic tryptophan fluorescence, and TNS fluorescence and by determination of molecular masses and chaperone function which was assessed as the ability to suppress target protein aggregation or enhance target protein refolding. Mutation of Arg-116 to a Cys or Gly showed very similar changes in structure, oligomerization, and chaperone function which suggest that the presence of this Cys per se is not the cause of the changes. The R116K mutant, on the other hand, had nearly the same structure, oligomeric size, and chaperone function as alphaA-wt, whereas the mutant with an acidic amino acid in this position, R116D, showed drastic changes in protein structure. Thus, a positive charge must be preserved at this position for the structural and functional integrity of alphaA-crystallin.     

A novel mutation (F71L) in αA-Crystallin with defective chaperone-like function associated with age-related cataract

Age-related cataract (ARC) is a multifactorial disease and the leading cause of blindness worldwide. Genetic predisposition in association with other etiological factors may contribute to ARC. However, gene mutation studies on ARC are scanty. In the present work, we identified a genetic variation (F71L) in the exon-2 of CRYAA (αA-crystallin) gene in three unrelated female sporadic cases among 711 ARC patients but not in 265 normal non-cataractous controls by SSCP and RFLP analysis. By comparing human recombinant wild-type and F71L-αA-crystallin, we characterized the functional significance of this missense mutation. Chromatography, fluorescence and far- and near-UV CD studies indicated that F71L missense mutation did not significantly affect the apparent molecular mass, secondary and tertiary structures and hydrophobicity of αA-crystallin. While the mutant αA-crystallin displayed significant (35–90%) loss of chaperone-like activity (CLA) in thermal aggregation of carbonic anhydrase, βL- and γ-crystallins, it showed moderate (10–50%) loss in CLA in DTT-induced aggregation of insulin and lysozyme. This is the first report of an αA-F71L mutation being associated with ARC and suggests that ARC in individuals carrying this mutation (F71L) might be due to the overall loss of in vivo chaperone activity due to interaction with other environmental factors.     

Mechanism of small heat shock protein function in vivo: a knock-in mouse model demonstrates that the R49C mutation in alpha A-crystallin enhances protein insolubility and cell death

alphaA-crystallin (Cryaa/HSPB4) is a small heat shock protein and molecular chaperone that prevents nonspecific aggregation of denaturing proteins. Several point mutations in the alphaA-crystallin gene cause congenital human cataracts by unknown mechanisms. We took a novel approach to investigate the molecular mechanism of cataract formation in vivo by creating gene knock-in mice expressing the arginine 49 to cysteine mutation (R49C) in alphaA-crystallin (alphaA-R49C). This mutation has been linked with autosomal dominant hereditary cataracts in a four-generation Caucasian family. Homologous recombination in embryonic stem cells was performed using a plasmid containing the C to T transition in exon 1 of the cryaa gene. alphaA-R49C heterozygosity led to early cataracts characterized by nuclear opacities. Unexpectedly, alphaA-R49C homozygosity led to small eye phenotype and severe cataracts at birth. Wild type littermates did not show these abnormalities. Lens fiber cells of alphaA-R49C homozygous mice displayed an increase in cell death by apoptosis mediated by a 5-fold decrease in phosphorylated Bad, an anti-apoptotic protein, but an increase in Bcl-2 expression. However, proliferation measured by in vivo bromodeoxyuridine labeling did not decline. The alphaA-R49C heterozygous and homozygous knock-in lenses demonstrated an increase in insoluble alphaA-crystallin and alphaB-crystallin and a surprising increase in expression of cytoplasmic gamma-crystallin, whereas no changes in beta-crystallin were observed. Co-immunoprecipitation analysis showed increased interaction between alphaA-crystallin and lens substrate proteins in the heterozygous knock-in lenses. To our knowledge this is the first knock-in mouse model for a crystallin mutation causing hereditary human cataract and establishes that alphaA-R49C promotes protein insolubility and cell death in vivo.     

Three-dimensional solution structure of an archaeal FKBP with a dual function of peptidyl prolyl cis-trans isomerase and chaperone-like activities

Here we report the solution structure of an archaeal FK506-binding protein (FKBP) from a thermophilic archaeum, Methanococcus thermolithotrophicus (MtFKBP17), which has peptidyl prolyl cis-trans isomerase (PPIase) and chaperone-like activities, to reveal the structural basis for the dual function. In addition to a typical PPIase domain, a newly identified domain is formed in the flap loop by a 48-residue insert that is required for the chaperone-like activity. The new domain, called IF domain (the Insert in the Flap), is a novel-folding motif and exposes a hydrophobic surface, which we consider to play an important role in the chaperone-like activity.     

Differential rate constants of racemization of aspartyl and asparaginyl residues in human alpha A-crystallin mutants

Asp58 and Asp151 in alpha A-crystallin of human eye lenses become highly inverted and isomerized to d-beta-Asp residues with age. Racemization was previously shown to proceed rapidly when the residue on the carboxyl side of the Asp residue is small. Asn was also demonstrated to be more susceptible to racemization than Asp in protein. In this study, the changes of rate constants for racemization at Asp58 and Asp151 and at Asn58 and Asn151 were investigated using D58N, S59T, D151N and A152V mutants obtained through site-directed mutagenesis. The rate constant of racemization at Asn151 in D151N was found to be 1.5 times more rapid than Asp151 in the wild-type. For A152V, the rate constant at Asp151 was 1/4 that of the wild-type. There were no significant differences in the rate constants of racemization for both Asp58 and Asn58 residues. The aggregate size of D58N, S59T and D151N mutants increased or increased in polydispersity and their chaperone activities decreased. The size and chaperone activity of A152V was unchanged. These results suggest that structures close to Asp58 and Asp151 residues in the protein affect the rate constant of Asp racemization and the size and chaperone function of alpha A-crystallin.     

Clinical Significance of Cerebral Microbleeds Locations in CADASIL with R544C NOTCH3 Mutation

MethodsThis is a cohort study of patients who were diagnosed with genotype-confirmed R544C-mutation CADASIL. Primary neurologic symptoms were recorded. Symptomatic strokes were defined as transient ischemic attack, ischemic strokes and hemorrhagic strokes. CMBs were defined as focal areas of round signal loss on T2*-weighted gradient echo planar images with a diameter of less than 10 mm. The locations of CMBs were divided into lobar, basal ganglia, thalamus, brain stem and cerebellum. Multiple logistic regressions were performed to identify the epidemiologic or vascular risk factors associated with symptomatic stroke in patients with CADASIL.ResultsAmong total of 51 subjects in this cohort, CMBs were present in 20 of 32 patients (64.5%) in the symptomatic stroke-group and in 8 of 19 patients (42.1%) in the non-stroke group (p = 0.16). CMBs were observed more frequently in the basal ganglia (p<0.001) and the cerebellum (p<0.018) in the symptomatic stoke group compared to the non-stroke group. The mean number of CMBs was significantly higher in the symptomatic stroke group (15.4±18.0 lesions per patients with CMBs) versus those without symptomatic stroke (3.3±3.0 lesions per patients with CMBs) (p = 0.003). Hypertension was an independent risk factor for symptomatic stroke in CADASIL (p = 0.014). It was independently associated with CMBs locations as basal ganglia (p = 0.016), thalamus (p = 0.010), brainstem (p = 0.044), and cerebellum (p = 0.049). However, It was not independently associated with CMBs on lobar lesion (p = 0.152).ConclusionsIn this study hypertension was an independent predictor of CMBs presence in specific brain locations, as well as symptomatic stroke in the CADASIL patients. The distribution and burden of CMBs might be a clinically useful marker for the risk of symptomatic stroke. However, further prospective studies on the relationship between CMBs distribution and symptomatic stroke are required in order to support these preliminary findings.     

R54C Mutation of NOTCH3 Gene in the First Rungus Family with CADASIL

Cerebral autosomal dominant arteriopathy with subcortical infarcts and leukoencephalopathy (CADASIL) is a rare hereditary stroke caused by mutations in NOTCH3 gene. We report the first case of CADASIL in an indigenous Rungus (Kadazan-Dusun) family in Kudat, Sabah, Malaysia confirmed by a R54C (c.160C>T, p.Arg54Cys) mutation in the NOTCH3. This mutation was previously reported in a Caucasian and two Korean cases of CADASIL. We recruited two generations of the affected Rungus family (n = 9) and found a missense mutation (c.160C>T) in exon 2 of NOTCH3 in three siblings. Two of the three siblings had severe white matter abnormalities in their brain MRI (Scheltens score 33 and 50 respectively), one of whom had a young stroke at the age of 38. The remaining sibling, however, did not show any clinical features of CADASIL and had only minimal changes in her brain MRI (Scheltens score 17). This further emphasized the phenotype variability among family members with the same mutation in CADASIL. This is the first reported family with CADASIL in Rungus subtribe of Kadazan-Dusun ethnicity with a known mutation at exon 2 of NOTCH3. The penetrance of this mutation was not complete during the course of this study.     

Requirement for class II phosphoinositide 3-kinase C2alpha in maintenance of glomerular structure and function

An early lesion in many kidney diseases is damage to podocytes, which are critical components of the glomerular filtration barrier. A number of proteins are essential for podocyte filtration function, but the signaling events contributing to development of nephrotic syndrome are not well defined. Here we show that class II phosphoinositide 3-kinase C2α (PI3KC2α) is expressed in podocytes and plays a critical role in maintaining normal renal homeostasis. PI3KC2α-deficient mice developed chronic renal failure and exhibited a range of kidney lesions, including glomerular crescent formation and renal tubule defects in early disease, which progressed to diffuse mesangial sclerosis, with reduced podocytes, widespread effacement of foot processes, and modest proteinuria. These findings were associated with altered expression of nephrin, synaptopodin, WT-1, and desmin, indicating that PI3KC2α deficiency specifically impacts podocyte morphology and function. Deposition of glomerular IgA was observed in knockout mice; importantly, however, the development of severe glomerulonephropathy preceded IgA production, indicating that nephropathy was not directly IgA mediated. PI3KC2α deficiency did not affect immune responses, and bone marrow transplantation studies also indicated that the glomerulonephropathy was not the direct consequence of an immune-mediated disease. Thus, PI3KC2α is critical for maintenance of normal glomerular structure and function by supporting normal podocyte function.     

Changes in the capsid structure and stability of defective particles of bacteriophage R17.

Serological and chemical methods were used to compare the capsid structure and stability of R17 phage and amA31 defective particles. Immunodiffusion analysis demonstrated identity between intact R17 and amA31 capside and between dissociated subunits of both R17 and amA31 and purified coat protein. Radioimmunoassays detected an antibody in R17 antisera that binds to intact R17 but could not be absorbed from R17 antisera with amA31. The R17 antibody remaining in amA31-absorbed sera did not neutralize infectivity of R17 phage. Differences between the surface composition of R17 and amA31 capsids were also detected by iodination. Capsids of R17 bound approximately four times more 125I than amA31, which was accounted for by a decreased 125I labeling of coat protein. Finally, amA31 capsids dissociated under milder conditions of sodium dodecyl sulfate treatment than R17 capsids. The sodium dodecyl sulfate dissociation of both R17 and amA31 capsids resulted in the formation of a transient 38,000-dalton intermediate, which subsequently dissociated to coat protein monomers. Preparations of dissociated R17 capsids also contained assembly protein was also found in preparations of dissociated amA31 capsids.     

Comparison of d-aspartic acid contents in alpha A-crystallin from normal and age-matched cataractous human lenses

We have previously shown that biologically uncommon d-beta-aspartic acids (Asp) were localized with very high contents at Asp-151 and Asp-58 of alpha A-crystallin from aged human lenses. The amounts increased with age, and we have proposed the mechanism of this reaction. In the present study, in order to elucidate the possible relationship between the formation of d-beta-aspartic acids in alpha A-crystallin and cataract formation, we measured the d/l ratio of beta-Asp-151 of alpha A-crystallin from both cataractous and age-matched normal human lenses. alpha A-crystallin from total proteins of cataractous and age-matched normal lenses was prepared, followed by tryptic digestion and quantification of d/l ratios for tryptic fragments containing the alpha- and beta-aspartate forms of Asp-151 residues. The results demonstrate that the d/l ratio of beta-Asp-151 of alpha A-crystallin from normal lenses is not statistically significant from that of alpha A-crystallin from cataractous lenses, suggesting that formation of this biologically uncommon amino acid may not play a role in human cataractogenesis.     

Acute Inotropic and Lusitropic Effects of Cardiomyopathic R9C Mutation of Phospholamban

A naturally occurring R9C mutation of phospholamban (PLB) triggers cardiomyopathy and premature death by altering regulation of sarco/endoplasmic reticulum calcium-ATPase (SERCA). The goal of this study was to investigate the acute physiological consequences of the R9C-PLB mutation on cardiomyocyte calcium kinetics and contractility. We measured the physiological consequences of R9C-PLB mutation on calcium transients and sarcomere shortening in adult cardiomyocytes. In contrast to studies of chronic R9C-PLB expression in transgenic mice, we found that acute expression of R9C-PLB exerts a positively inotropic and lusitropic effect in cardiomyocytes. Importantly, R9C-PLB exhibited blunted sensitivity to frequency potentiation and β-adrenergic stimulation, two major physiological mechanisms for the regulation of cardiac performance. To identify the molecular mechanism of R9C pathology, we quantified the effect of R9C on PLB oligomerization and PLB-SERCA binding. FRET measurements in live cells revealed that R9C-PLB exhibited an increased propensity for oligomerization, and this was further increased by oxidative stress. The R9C also decreased PLB binding to SERCA and altered the structure of the PLB-SERCA regulatory complex. The structural change after oxidative modification of R9C-PLB was similar to that observed after PLB phosphorylation. We conclude that R9C mutation of PLB decreases SERCA inhibition by decreasing the amount of the regulatory complex and altering its conformation. This has an acute inotropic/lusitropic effect but yields negative consequences of impaired frequency potentiation and blunted β-adrenergic responsiveness. We envision a self-reinforcing mechanism beginning with phosphomimetic R9C-PLB oxidation and loss of SERCA inhibition, leading to impaired calcium regulation and heart failure.     

Tissue-specific expression of the chicken alpha A-crystallin gene in cultured lens epithelia and transgenic mice

The present experiments show that the single gene for the lens-specific protein alpha A-crystallin of chickens and mice uses a different subset of cis- and trans-acting regulatory elements for expression in transfected embryonic chicken lens epithelial cells. A chicken alpha A-crystallin-chloramphenicol acetyltransferase (CAT) fusion gene required 162 base pairs whereas the murine alpha A-crystallin-CAT fusion gene required only 111 base pairs of 5'-flanking sequences for efficient tissue-specific expression in the transfected chicken lens cells. Gel retardation and competition experiments were performed using embryonic chicken lens nuclear extract and oligodeoxynucleotides identical to the 5'-flanking region of the chicken (-170/-111) and murine (-111/-88 and -88/-55) alpha A-crystallin gene. The results indicated that these homologous promoters use different nuclear factors for function. Methylation interference analysis identified a dyad of symmetry (CTGGTTCCCACCAG) at position -153 to -140 in the chicken alpha A-crystallin promoter which binds one or more lens nuclear factors. Gel mobility shift experiments using nuclear extracts of brain, reticulocytes, and muscle of embryonic chickens or HeLa cells suggested that the factor(s) binding to the chicken alpha A-crystallin gene promoter sequences are not lens specific. Despite differences in the functional and protein-binding properties of the alpha A-crystallin gene promoter of chickens and mice, expression of the chicken alpha A-crystallin-CAT fusion gene in transgenic mice was lens specific, consistent with a common underlying mechanism for expression of the alpha A-crystallin gene in chickens and mice.