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.     

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.     

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.     

Residue R120 is essential for the quaternary structure and functional integrity of human alphaB-crystallin

The missense mutation Arg-120 to Gly (R120G) in the human alphaBeta-crystallin sequence has been reported to be associated with autosomal dominant myopathy, cardiomyopathy, and cataract. Previous studies of the mutant showed a significant ability to aggregate in cultured cells and an increased oligomeric size coupled to an important loss of the chaperone-like activity in vitro. The aim of this study was to further analyze the role of the R120 residue in the structural and functional properties of alphaBeta-crystallin. The following mutants were generated, Arg-120 to Gly (R120G), Cys (R120C), Lys (R120K), and Asp (R120D). In cellulo, after expression in two cultured cell lines, NIH-3T3 and Cos-7, the capacity of the wild-type and mutant crystallins to aggregate was evaluated and the protein location was determined by immunofluorescence. In vitro, the wild-type and mutant crystallins were expressed in Escherichia coli cells, purified by size exclusion chromatography, and characterized using dynamic light scattering, electron microscopy, and chaperone-like activity assays. Aggregate sizes in cellulo and in vitro were analyzed. The whole of the data showed that the preservation of an Arg residue at position 120 of alphaBeta-crystallin is critical for the structural and functional integrity of the protein and that each mutation results in specific changes in both structural and functional characteristics.     

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.     

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.     

Mutation of R116C results in highly oligomerized alpha A-crystallin with modified structure and defective chaperone-like function

An autosomal dominant congenital cataract in human is associated with mutation of Arg-116 to Cys (R116C) in alpha A-crystallin. To investigate the molecular basis of cataract formation, rat alpha A-crystallin cDNA was cloned into pET-23d(+), and the site-directed mutants S142C (similar to wild-type human alpha A) and R116C/S142C or R116C (similar to human R116C variant) were generated. These were expressed in E. coli and the recombinant alpha A-crystallins purified by Sephacryl size-exclusion chromatography. The chaperone-like function of mutant R116C determined at 37 degrees C with insulin and alcohol dehydrogenase as target proteins was about 40% lower than those of wild-type and mutant S142C. Based on size-exclusion chromatography data, the oligomeric size of the R116C mutant was about 2000 kDa at 25 degrees C, 1400 kDa at 37 degrees C, and 900 kDa at 45 degrees C. In comparison, alpha A-wild-type and alpha A-S142C ranged from 477 to 581 kDa. Heat stability studies corroborated the effect of temperature on the dynamic quaternary structure of the R116C mutant. Circular dichroism spectra showed secondary and tertiary structural changes, and ANS fluorescence spectra showed loss of surface hydrophobicity in the R116C mutant. These findings suggest that the molecular basis for the congenital cataract with the alpha A-R116C mutation is due to the generation of a highly oligomerized alpha A-crystallin having a modified structure and decreased chaperone-like function.     

Structure, stability, and chaperone function of alphaA-crystallin: role of N-terminal region

Small heat shock protein alphaA-crystallin, the major protein of the eye lens, is a molecular chaperone. It consists of a highly conserved central domain flanked by the N-terminal and C-terminal regions. In this article we studied the role of the N-terminal domain in the structure and chaperone function of alphaA-crystallin. Using site directed truncation we raised several deletion mutants of alphaA-crystallin and their protein products were expressed in Escherichia coli. Size exclusion chromatography of these purified proteins showed that deletion from the N-terminal beyond the first 20 residues drastically reduced the oligomeric association of alphaA-crystallin and its complete removal resulted in a tetramer. Chaperone activity of alphaA-crystallin, determined by thermal and nonthermal aggregation and refolding assay, decreased with increasing length of deletion and little activity was observed for the tetramer. However it was revealed that N-terminal regions were not responsible for specific recognition of natural substrates and that low affinity substrate binding sites existed in other part of the molecule. The number of exposed hydrophobic sites and the affinity of binding hydrophobic probe bis-ANS as well as protein substrates decreased with N-terminal deletion. The stability of the mutant proteins decreased with increase in the length of deletion. The role of thermodynamic stability, oligomeric size, and surface hydrophobicity in chaperone function is discussed. Detailed analysis showed that the most important role of N-terminal region is to control the oligomerization, which is crucial for the stability and in vivo survival of this protein molecule.     

Effect of site-directed mutagenesis of methylglyoxal-modifiable arginine residues on the structure and chaperone function of human alphaA-crystallin

We reported previously that chemical modification of human alphaA-crystallin by a metabolic dicarbonyl compound, methylglyoxal (MGO), enhances its chaperone-like function, a phenomenon which we attributed to formation of argpyrimidine at arginine residues (R) 21, 49, and 103. This structural change removes the positive charge on the arginine residues. To explore this mechanism further, we replaced these three R residues with a neutral alanine (A) residue one at a time or in combination and examined the impact on the structure and chaperone function. Measurement of intrinsic tryptophan fluorescence and near-UV CD spectra revealed alteration of the microenvironment of aromatic amino acid residues in mutant proteins. When compared to wild-type (wt) alphaA-crystallin, the chaperone function of R21A and R103A mutants increased 20% and 18% as measured by the insulin aggregation assay and increased it as much as 39% and 28% when measured by the citrate synthase (CS) aggregation assay. While the R49A mutant lost most of its chaperone function, R21A/R103A and R21A/R49A/R103A mutants had slightly better function (6-14% and 10-14%) than the wt protein in these assays. R21A and R103A mutants had higher surface hydrophobicity than wt alphaA-crystallin, but the R49A mutant had lower hydrophobicity. R21A and R103A mutants, but not the R49A mutant, were more efficient than wt protein in refolding guanidine hydrochloride-treated malate dehydrogenase to its native state. Our findings indicate that the positive charges on R21, R49, and R103 are important determinants of the chaperone function of alphaA-crystallin and suggest that chemical modification of arginine residues may play a role in protein aggregation during lens aging and cataract formation.     

Paradoxical effects of substitution and deletion mutation of Arg56 on the structure and chaperone function of human alphaB-crystallin

Human alphaB-crystallin is a small heat-shock protein that functions as a molecular chaperone. Recent studies indicate that deletion of a peptide (54FLRAPSWF61) from its N-terminus makes it a better chaperone, and this particular sequence is thought to participate in substrate interaction and subunit exchange with alphaA-crystallin. To determine whether the positive charge on arginine 56 (R56) influences these functions, we prepared human alphaB-crystallin mutants in which R56 was deleted (DeltaR56) or replaced by alanine (R56A). To determine if the effects are specific to R56, we generated two additional mutant proteins in which the two neighboring amino acids were deleted (DeltaL55 and DeltaA57). Dynamic light scattering studies suggested that none of the mutations affected the oligomeric mass of the protein. Far-ultraviolet circular dichroism (UV CD) spectra revealed greater helicity in the secondary structures of R56A and DeltaR56 compared to that of the wild-type (Wt) protein. Near-UV CD spectra showed that the tertiary structure is perturbed in all mutants. Insulin and citrate synthase aggregation assays showed 38 and 30% improvement of chaperone function in DeltaR56 compared to that of the Wt. In contrast, the R56A mutant lost most of its chaperone function. Deletion mutants, DeltaL55 and DeltaA57, showed no significant changes in the chaperone function compared to that of the Wt. The DeltaR56 mutant had a higher surface hydrophobicity than the Wt, but the R56A mutant had a lower hydrophobicity. Our data show paradoxical effects of the deletion and substitution of R56 and imply that the chaperone function of human alphaB-crystallin is dictated not only by the positive charge on R56 but also by the conformational change that it bestows on the protein.     

AlphaA-crystallin interacting regions in the small heat shock protein, alphaB-crystallin

Amino acid sequences of alphaB-crystallin, involved in interaction with alphaA-crystallin, were determined by using peptide scans. Positionally addressable 20-mer overlapping peptides, representing the entire sequence of alphaB-crystallin, were synthesized on a PVDF membrane. The membrane was blocked with albumin and incubated with purified alphaA-crystallin. Probing the membrane with alphaA-crystallin-specific antibodies revealed residues 42-57, 60-71, and 88-123 in alphaB-crystallin to interact with alphaA-crystallin. Residues 42-57 and 60-71 interacted more strongly with alphaA-crystallin than the 88-123 sequence of alphaB-crystallin. Binding of one of the alphaB peptides (42-57) to alphaA-crystallin was also confirmed by gel filtration studies and HPLC analysis. The alphaB-crystallin sequences involved in interaction with alphaA-crystallin were distinct from the chaperone sites reported earlier as binding of the alphaB sequence from residues 42-57 does not alter the chaperone-like function of alphaA-crystallin. To identify the critical residues involved in interaction with alphaA-crystallin, R50G and P51A mutants of alphaB-crystallin were made and tested for their ability to interact with alphaA-crystallin. The oligomeric size and hydrophobicity of the mutants were similar. Circular dichroism studies showed that the P51A mutation increased the alpha-helical content of the protein. While the alphaBR50G mutant showed chaperone-like activity similar to wild-type alphaB, alphaBP51A showed reduced chaperone function. Fluorescence resonance energy transfer studies showed that the P51A mutation decreased the rate of subunit exchange with alphaA by 63%, whereas the R50G mutation reduced the exchange rate by 23%. Similar to wild-type alphaB, alphaB-crystallin peptide (42-57) effectively competed with alphaBP51A and alphaBR50G for interaction with alphaA. Thus, our studies showed that the alphaB-crystallin sequence (42-57) is one of the interacting regions in alphaB and alphaA oligomer formation.     

Structural and functional consequences of the mutation of a conserved arginine residue in alphaA and alphaB crystallins.

A point mutation of a highly conserved arginine residue in alphaA and alphaB crystallins was shown to cause autosomal dominant congenital cataract and desmin-related myopathy, respectively, in humans. To study the structural and functional consequences of this mutation, human alphaA and alphaB crystallin genes were cloned and the conserved arginine residue (Arg-116 in alphaA crystallin and Arg-120 in alphaB crystallin) mutated to Cys and Gly, respectively, by site-directed mutagenesis. The recombinant wild-type and mutant proteins were expressed in Escherichia coli and purified. The mutant and wild-type proteins were characterized by SDS-polyacrylamide gel electrophoresis, Western immunoblotting, gel permeation chromatography, fluorescence, and circular dichroism spectroscopy. Biophysical studies reveal significant differences between the wild-type and mutant proteins. The chaperone-like activity was studied by analyzing the ability of the recombinant proteins to prevent dithiothreitol-induced aggregation of insulin. The mutations R116C in alphaA crystallin and R120G in alphaB crystallin reduce the chaperone-like activity of these proteins significantly. Near UV circular dichroism and intrinsic fluorescence spectra indicate a change in tertiary structure of the mutants. Far UV circular dichroism spectra suggest altered packing of the secondary structural elements. Gel permeation chromatography reveals polydispersity for both of the mutant proteins. An appreciable increase in the molecular mass of the mutant alphaA crystallin is also observed. However, the change in oligomer size of the alphaB mutant is less significant. These results suggest that the conserved arginine of the alpha-crystallin domain of the small heat shock proteins is essential for their structural integrity and subsequent in vivo function.     

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.     

Glutathionylation of peroxiredoxin I induces decamer to dimers dissociation with concomitant loss of chaperone activity

Reversible protein glutathionylation, a redox-sensitive regulatory mechanism, plays a key role in cellular regulation and cell signaling. Peroxiredoxins (Prxs), a family of peroxidases that is involved in removing H(2)O(2) and organic hydroperoxides, are known to undergo a functional change from peroxidase to molecular chaperone upon overoxidation of its catalytic cysteine. The functional change is caused by a structural change from low molecular weight oligomers to high molecular weight complexes that possess molecular chaperone activity. We reported earlier that Prx I can be glutathionylated at three of its cysteine residues, Cys52, -83, and -173 [Park et al. (2009) J. Biol. Chem., 284, 23364]. In this study, using analytical ultracentrifugation analysis, we reveal that glutathionylation of Prx I, WT, or its C52S/C173S double mutant shifted its oligomeric status from decamers to a population consisting mainly of dimers. Cys83 is localized at the putative dimer-dimer interface, implying that the redox status of Cys83 may play an important role in stabilizing the oligomeric state of Prx I. Studies with the Prx I (C83S) mutant show that while Cys83 is not essential for the formation of high molecular weight complexes, it affects the dimer-decamer equilibrium. Glutathionylation of the C83S mutant leads to accumulation of dimers and monomers. In addition, glutathionylation of Prx I, both the WT and C52S/C173S mutants, greatly reduces their molecular chaperone activity in protecting citrate synthase from thermally induced aggregation. Together, these results reveal that glutathionylation of Prx I promotes changes in its quaternary structure from decamers to smaller oligomers and concomitantly inactivates its molecular chaperone function.     

In vivo acetylation identified at lysine 70 of human lens alphaA-crystallin.

Posttranslational modification of protein lysyl residues that change the net charge of the molecule may alter the protein conformation. Such modifications are of particular significance among lens proteins, because conformational changes are associated with the development of cataract. A previously unidentified acetylated form of alphaA-crystallin has been isolated from the water-soluble portion of human lenses. The alphaA-crystallins were fractionated by anion exchange HPLC into seven peaks, each containing more than one form of alphaA-crystallin. The previously reported deamidated and phosphorylated forms were identified by their molecular masses, determined by electrospray ionization mass spectrometry. In addition to these modifications, approximately 5% of alphaA-crystallin had a modification that decreased the charge by one and increased the molecular mass by 42 u. This modification, identified as acetylation, was located uniquely at Lys 70. Like any modification that alters the surface charge, acetylation may affect protein conformation and intermolecular interactions, thereby altering the solubility or chaperone properties of alphaA-crystallin. Acetylation of lysine 70 is potentially significant since it is located in a region that has been implicated in the chaperone activity of alphaA-crystallin.     

A mutation linked with autism reveals a common mechanism of endoplasmic reticulum retention for the alpha,beta-hydrolase fold protein family

A mutation linked to autistic spectrum disorders encodes an Arg to Cys replacement in the C-terminal portion of the extracellular domain of neuroligin-3. The solvent-exposed Cys causes virtually complete retention of the protein in the endoplasmic reticulum when the protein is expressed in transfected cells. An identical Cys substitution was reported for butyrylcholinesterase through genotyping patients with post-succinylcholine apnea. Neuroligin, butyrylcholinesterase, and acetylcholinesterase are members of the alpha,beta-hydrolase fold family of proteins sharing sequence similarity and common tertiary structures. Although these proteins have distinct oligomeric assemblies and cellular dispositions, homologous Arg residues in neuroligin-3 (Arg-451), in butyrylcholinesterase (Arg-386), and in acetylcholinesterase (Arg-395) are conserved in all studied mammalian species. To examine whether an homologous Arg to Cys mutation affects related proteins similarly despite their differing capacities to oligomerize, we inserted homologous mutations in the acetylcholinesterase and butyrylcholinesterase cDNAs. Using confocal fluorescence microscopy and analysis of oligosaccharide processing, we find that the homologous Arg to Cys mutation also results in endoplasmic reticulum retention of the two cholinesterases. Small quantities of mutated acetylcholinesterase exported from the cell retain activity but show a greater K(m), a much smaller k(cat), and altered substrate inhibition. The nascent proteins associate with chaperones during processing, but the mutation presumably restricts processing through the endoplasmic reticulum and Golgi apparatus, because of local protein misfolding and inability to oligomerize. The mutation may alter the capacity of these proteins to dissociate from their chaperone prior to oligomerization and processing for export.     

Cover Image,Volume 88, Issue 6

Hsp16.3, a molecular chaperone, plays a vital role in the growth and survival of Mycobacterium tuberculosis inside the host. We previously reported that deletion of three amino acid residues (¹⁴²STN¹⁴⁴) from C-terminal extension (CTE) of Hsp16.3 triggers its structural perturbation and increases its chaperone activity, which reaches its apex upon the deletion of its entire CTE (¹⁴¹RSTN¹⁴⁴). Thus, we hypothesized that Arg141 (R141) and Ser142 (S142) in the CTE of Hsp16.3 possibly hold the key in maintaining its native-like structure and chaperone activity. To test this hypothesis, we generated two deletion mutants in which R141 and S142 were deleted individually (Hsp16.3ΔR141 and Hsp16.3ΔS142) and three substitution mutants in which R141 was replaced by lysine (Hsp16.3R141K), alanine (Hsp16.3R141A), and glutamic acid (Hsp16.3R141E), respectively. Hsp16.3ΔS142 or Hsp16.3R141K mutant has native-like structure and chaperone activity. Deletion of R141 from the CTE (Hsp16.3ΔR141) perturbs the secondary and tertiary structure, lowers the subunit exchange dynamics and decreases the chaperone activity of Hsp16.3. But, the substitution of R141 with alanine (Hsp16.3R141A) or glutamic acid (Hsp16.3R141E) perturbs its secondary and tertiary structure. Surprisingly, such charge tampering of R141 enhances the subunit exchange dynamics and chaperone activity of Hsp16.3. Interestingly, neither the deletion of R141/S142 nor the substitution of R141 with lysine, alanine and glutamic acid affects the oligomeric mass/size of Hsp16.3. Overall, our study suggests that R141 (especially the positive charge on R141) plays a crucial role in maintaining the native-like structure as well as in regulating subunit exchange dynamics and chaperone activity of Hsp16.3.     

Interhelical packing modulates conformational flexibility in the lactose permease of Escherichia coli

A key to obtaining an X-ray structure of the lactose permease of Escherichia coli (LacY) (Abramson, J., Smirnova, I., Kasho, V., Verner, G., Kaback, H. R., and Iwata, S. (2003) Science 301, 549-716) was the use of a mutant in which Cys154 (helix V) is replaced with Gly. LacY containing this mutation strongly favors an inward-facing conformation, which binds ligand with high affinity, but catalyzes little transport and exhibits few if any of the ligand-dependent conformational changes observed with wild-type LacY. The X-ray structure demonstrates that helix V crosses helix I in the approximate middle of the membrane in such a manner that Cys154 lies close to Gly24 (helix I). Therefore, it seems likely that replacing Cys154 with Gly may lead to tighter packing between helices I and V, thereby resulting in the phenotype observed. Consistently, replacement of Gly24 with Cys in the C154G mutant rescues significant transport activity, and the mutant exhibits properties similar to wild-type LacY with respect to substrate binding and thermostability. However, the only other replacements that rescue transport to any extent whatsoever are Val and Asp, both of which are much less effective than Cys. The results suggest that, although helix packing probably plays an important role with respect to the properties of the C154G mutant, the ability of Cys at position 24 to rescue transport activity of C154G is more complicated than simple replacement of bulk between positions 24 and 154. Rather, activity is dependent on more subtle interactions between the helices, and mutations that disrupt interactions between helix IV and loop 6-7 or between helices II and IV also rescue transport in the C154G mutant.     

Characteristics of super alphaA-crystallin, a product of in vitro exon shuffling

alphaA-Crystallin, a small heat shock protein with chaperone-like activity, forms dynamic multimeric complexes. Recently we described the spontaneous generation of a mutant protein (super alphaA-crystallin) by exon duplication arisen via exon shuffling confirming a classic hypothesis by Gilbert [Nature 271 (1978) 501]. Comparison of super alphaA-crystallin, which is viable in a mouse skeletal muscle cell line, with normal alphaA-crystallin shows that it has diminished thermostability, increased exposure of hydrophobic patches, a larger complex size and lost its chaperone activity. However, super alphaA-crystallin subunits exchange as readily between complexes as does normal alphaA-crystallin. These data indicate that chaperone-like activity may vanish independent of subunit hydrophobicity and exchangeability.     

The tRNA-dependent activation of arginine by arginyl-tRNA synthetase requires inter-domain communication

The tRNA-dependent amino acid activation catalyzed by mammalian arginyl-tRNA synthetase has been characterized. A conditional lethal mutant of Chinese hamster ovary cells that exhibits reduced arginyl-tRNA synthetase activity (Arg-1), and two of its derived revertants (Arg-1R4 and Arg-1R5) were analyzed at the structural and functional levels. A single nucleotide change, resulting in a Cys to Tyr substitution at position 599 of arginyl-tRNA synthetase, is responsible for the defective phenotype of the thermosensitive and arginine hyper-auxotroph Arg-1 cell line. The two revertants have a single additional mutation resulting in a Met222 to Ile change for Arg-1R4 or a Tyr506 to Ser change for Arg-1R5. The corresponding mutant enzymes were expressed in yeast and purified. The Cys599 to Tyr mutation affects both the thermal stability of arginyl-tRNA synthetase and the kinetic parameters for arginine in the ATP-PP(i) exchange and tRNA aminoacylation reactions. This mutation is located underneath the floor of the Rossmann fold catalytic domain characteristic of class 1 aminoacyl-tRNA synthetases, near the end of a long helix belonging to the alpha-helix bundle C-terminal domain distinctive of class 1a synthetases. For the Met222 to Ile revertant, there is very little effect of the mutation on the interaction of arginyl-tRNA synthetase with either of its substrates. However, this mutation increases the thermal stability of arginyl-tRNA synthetase, thereby leading to reversion of the thermosensitive phenotype by increasing the steady-state level of the enzyme in vivo. In contrast, for the Arg-1R5 cell line, reversion of the phenotype is due to an increased catalytic efficiency of the C599Y/Y506S double mutant as compared to the initial C599Y enzyme. In light of the location of the mutations in the 3D structure of the enzyme modeled using the crystal structure of the closely related yeast arginyl-tRNA synthetase, the kinetic analysis of these mutants suggests that the obligatory tRNA-induced activation of the catalytic site of arginyl-tRNA synthetase involves interdomain signal transduction via the long helices that build the tRNA-binding domain of the enzyme and link the site of interaction of the anticodon domain of tRNA to the floor of the active site.