Disulfide bonds convert small heat shock protein Hsp16.3 from a chaperone to a non-chaperone: implications for the evolution of cysteine in molecular chaperones

Molecular chaperones mainly function in assisting newly synthesized polypeptide folding and protect non-native proteins from aggregation, with known structural features such as the ability of spontaneous folding/refolding and high conformational flexibility. In this report, we verified the assumption that the lack of disulfide bonds in molecular chaperones is a prerequisite for such unique structural features. Using small heat shock protein (one sub-class of chaperones) Hsp16.3 as a model system, our results show the following: (1) Cysteine-free Hsp16.3 wild type protein can efficiently exhibit chaperone activity and spontaneously refold/reassemble with high conformational flexibility. (2) Whereas Hsp16.3 G89C mutant with inter-subunit disulfide bonds formed seems to lose the nature of chaperone proteins, i.e., under stress conditions, it neither acts as molecular chaperone nor spontaneously refolds/reassembles. Structural analysis indicated that the mutant exists as an unstable molten globule-like state, which incorrectly exposes hydrophobic surfaces and irreversibly tends to form aggregates that can be suppressed by the other molecular chaperone (alpha-crystallin). By contrast, reduction of disulfide bond in the Hsp16.3 G89C mutant can significantly recover its character as a molecular chaperone. In light of these results, we propose that disulfide bonds could severely disturb the structure/function of molecular chaperones like Hsp16.3. Our results might not only provide insights into understanding the structural basis of chaperone upon binding substrates, but also explain the observation that the occurrence of cysteine in molecular chaperones is much lower than that in other protein families, subsequently being helpful to understand the evolution of protein family.     

The Assembly and Intermolecular Properties of the Hsp70-Tomm34-Hsp90 Molecular Chaperone Complex

Maintenance of protein homeostasis by molecular chaperones Hsp70 and Hsp90 requires their spatial and functional coordination. The cooperation of Hsp70 and Hsp90 is influenced by their interaction with the network of co-chaperone proteins, some of which contain tetratricopeptide repeat (TPR) domains. Critical to these interactions are TPR domains that target co-chaperone binding to the EEVD-COOH motif that terminates Hsp70/Hsp90. Recently, the two-TPR domain-containing protein, Tomm34, was reported to bind both Hsp70 and Hsp90. Here we characterize the structural basis of Tomm34-Hsp70/Hsp90 interactions. Using multiple methods, including pull-down assays, fluorescence polarization, hydrogen/deuterium exchange, and site-directed mutagenesis, we defined the binding activities and specificities of Tomm34 TPR domains toward Hsp70 and Hsp90. We found that Tomm34 TPR1 domain specifically binds Hsp70. This interaction is partly mediated by a non-canonical TPR1 two-carboxylate clamp and is strengthened by so far unidentified additional intermolecular contacts. The two-carboxylate clamp of the isolated TPR2 domain has affinity for both chaperones, but as part of the full-length Tomm34 protein, the TPR2 domain binds specifically Hsp90. These binding properties of Tomm34 TPR domains thus enable simultaneous binding of Hsp70 and Hsp90. Importantly, we provide evidence for the existence of an Hsp70-Tomm34-Hsp90 tripartite complex. In addition, we defined the basic conformational demands of the Tomm34-Hsp90 interaction. These results suggest that Tomm34 represents a novel scaffolding co-chaperone of Hsp70 and Hsp90, which may facilitate Hsp70/Hsp90 cooperation during protein folding.     

Ligand binding induces a sharp decrease in hydrophobicity of folate binding protein assessed by 1-anilinonaphthalene-8-sulphonate which suppresses self-association of the hydrophobic apo-protein

High affinity folate binding protein (FBP) regulates as a soluble protein and as a cellular receptor intracellular trafficking of folic acid, a vitamin of great importance to cell growth and division. We addressed two issues of potential importance to the biological function of FBP, a possible decrease of the surface hydrophobicity associated with the ligand-induced conformation change of FBP, and protein-inter-protein interactions involved in self-association of hydrophobic apo-FBP. The extrinsic fluorescent apolar dye 1-anilinonaphthalene-8-sulphonate (ANS) exhibited enhanced fluorescence intensity and a blueshift of emission maximum from 510-520 to 460-470nm upon addition of apo-FBP indicating binding to a strongly hydrophobic environment. Neither enhancement of fluorescence nor blueshift of ANS emission maximum occurred when folate-ligated holo-FBP replaced apo-FBP. The drastic decrease in surface hydrophobicity of holo-FBP could have bearings on the biological function of FBP since changes in surface hydrophobicity have critical effects on the biological function of receptors and transport proteins. ANS interacts with exposed hydrophobic surfaces on proteins and may thereby block and prevent aggregation of proteins (chaperone-like effect). Hence, hydrophobic interactions seemed to participate in the concentration-dependent self-association of apo-FBP which was suppressed by high ANS concentrations in light scatter measurements.     

Roles of molecular chaperones in cytoplasmic protein folding

Newly synthesized polypeptide chains must fold and assemble into unique three-dimensional structures in order to become functionally active. In many cases productive folding depends on assistance from molecular chaperones, which act in preventing off-pathway reactions during folding that lead to aggregation. The inherent tendency of incompletely folded polypeptide chains to aggregate is thought to be strongly enhanced$L in vivo *I$Lby the high macromolecular concentration of the cellular solution, resulting in crowding effects, and by the close proximity of nascent polypeptide chains during synthesis on polyribosomes. The major classes of chaperones acting in cytoplasmic protein folding are the Hsp70s and the chaperonins. Hsp70 chaperones shield the hydrophobic regions of nascent and incompletely folded chains, whereas the chaperonins provide a sequestered environment in which folding can proceed unimpaired by intermolecular interactions between non-native polypeptides. These two principles of chaperone action can function in a coordinated manner to ensure the efficient folding of a subset of cytoplasmic proteins.     

Transient aggregation and stable dimerization induced by introducing an Alzheimer sequence into a water-soluble protein

Transient contacts between denatured polypeptide chains are likely to play an important part in the initial stages of protein aggregation and fibrillation. To analyze the nature of such contacts, we have carried out a protein engineering study of the 102-residue protein U1A, which aggregates transiently in the wild-type form during refolding from the guanidinium chloride-denatured state. We have prepared a series of mutants with increased aggregation tendencies by increasing the homology between two beta-strands of U1A and the Alzheimer peptide (beta-AP). These mutants undergo transient aggregation during refolding, as measured by concentration dependence, double-jump experiments, and binding of ANS, a probe for exposed hydrophobic patches on protein surfaces. The propensity to aggregate increases with increasing homology to beta-AP. Further, the degree of transient ANS binding correlates reasonably well with the structural parameters recently shown to play a role in the fibrillation of natively unfolded proteins. Two mutants highly prone to transient aggregation, U1A-J and U1A-G, were also studied by NMR. Secondary structural elements of the U1A-J construct (with lower beta-AP homology) are very similar to those observed in U1A-wt. In contrast, the high-homology construct U1A-G exhibits local unfolding of the C-terminal helix, which packs against the beta-sheet in the wild-type protein. U1A-G is mainly dimeric according to (15)N spin relaxation data, and the dimer interface most likely involves the beta-sheet. Our data suggest that the transient aggregate relies on specific intermolecular interactions mediated by structurally flexible regions and that contacts may be formed in different beta-strand registers.     

Thermal induced conformational changes involved in the aggregation pathways of beta-lactoglobulin

Aggregation of proteins appears to be associated most often with conformational and structural changes that lead to exposure of some apolar residues. Depending on the native structure of the protein in exam, aggregation is a process that involves different mechanisms, whose time of occurrence and interplay can depend upon temperature. To single out information about the multistages of the aggregation pathway, here we investigate the thermally induced conformational and structural changes of the beta-lactoglobulin (BLG). The experimental approach consists in studying steady-state fluorescence spectra of intrinsic chromophores, two tryptophans, and Anylino-Naphthalene-Sulfonate dye (ANS) molecular probe. This technique revealed to be particularly suitable in investigating samples in the low concentration range and at the initial steps of the aggregation process. The Rayleigh scattering of the exciting light follows the growth of the intermolecular interactions at the same time. Complementary information is also obtained by circular dichroism (CD) measurements on samples in the same experimental conditions. The obtained data indicate a well-defined interconversion between quaternary, ternary and secondary structures, together with conformational rearrangements driven by hydrophobic interactions and intermolecular bonds. The results are also discussed in comparison with similar studies on BSA aggregation.     

Biochemical properties of Hsp70 chaperone system from Meiothermus ruber

The guanidine-hydrochloride (Gdn-HCl) and thermally induced unfolding of Hsp70 from Meiothermus ruber (Mru.Hsp70) were analysed using tryptophan fluorescence and 8-anilino-1-naphthalenesulfonic acid (ANS) binding. The ANS binding to Mru.Hsp70 showed both the increase in fluorescence intensity and a shift in emission maximum. Analysis of the unfolding profile of Mru.Hsp70 indicated that Gdn-HCl induced unfolding of Mru.Hsp70 occurred through intermediate species. The tryptophan and ANS fluorescence emission spectra revealed that ATP induced conformational change increased the thermal stability of Mru.Hsp70. The data obtained are similar to those of Escherichia coli DnaK. The ATP-ase activity of chaperones is fundamental for their biological activity. It this paper we demonstrate that, in contrast to Thermus thermophilus, both Mru.Hsp40 and Mru.Hsp22 co-chaperones affect the ATP-ase activity of Mru.Hsp70. The use of truncated Mru.Hsp40 proteins showed that full-length Mru.Hsp40 is required for stimulation of ATP-ase activity of Mru.Hsp70. E. coli GrpE could act as nucleotide exchange factor the in thermophilic Hsp70 ATP hydrolysis reaction. However, the role of E. coli DnaJ in the M. ruber ATP cycle needs further analysis. We selected the new substrate laccA suitable for determination of refolding activity of thermophilic chaperones.     

The unique chaperone operon of Thermotoga maritima: cloning and initial characterization of a functional Hsp70 and small heat shock protein.

The hyperthermophilic eubacterium Thermotoga maritima possesses an operon encoding an Hsp70 molecular chaperone protein and a protein with meaningful homology to the small heat shock protein family of chaperones. This represents the first demonstrated co-operon organization for these two important classes of molecular chaperones. We have cloned and initially characterized these proteins as functional chaperones in vitro: the Hsp70 is capable of ATP hydrolysis and substrate binding, and the small heat shock protein can suppress protein aggregation and stably bind a refolding-competent substrate. In addition, the primary sequence of the Hsp70 is used to infer the phylogenetic relationships of T. maritima, one of the deepest-branching eubacteria known.     

Exploring Mechanisms of Allosteric Regulation and Communication Switching in the Multiprotein Regulatory Complexes of the Hsp90 Chaperone with Cochaperones and Client Proteins: Atomistic Insights from Integrative Biophysical Modeling and Network Analysis of Conformational Landscapes

Understanding molecular principles underlying Hsp90 chaperone functions and modulation of client activity is fundamental to dissect activation mechanisms of many proteins. In this work, we performed a computational investigation of the Hsp90-Hsp70-Hop-CR client complex to examine allosteric regulatory mechanisms underlying dynamic chaperone interactions and principles of chaperone-dependent client recognition and remodeling. Conformational dynamics analysis using high-resolution coarse-grained simulations and ensemble-based local frustration analysis suggest that the Hsp90 chaperone could recognize and recruit the GR client by invoking reciprocal dynamic exchanges near the intermolecular interfaces with the client. Using mutational scanning of the intermolecular residues in the Hsp90-Hsp70-Hop-GR complex, we identified binding energy hotspots in the regulatory complex. Perturbation-based network analysis and dynamic fluctuations-based modeling of allosteric residue potentials are employed for a detailed analysis of allosteric interaction networks and identification of conformational communication switches. We found that allosteric interactions between the Hsp90, the client-bound Hsp70 and Hop cochaperone can define two allosteric residue clusters that control client recruitment in which the intrinsic Hsp70 allostery is exploited to mediate integration of the Hsp70-bound client into the Hsp90 chaperone system. The results suggest a model of dynamics-driven allostery that enables efficient client recruitment and loading through allosteric couplings between intermolecular interfaces and communication switch centers. This study showed that the Hsp90 interactions with client proteins may operate under dynamic-based allostery in which ensembles of preexisting conformational states and intrinsic allosteric pathways present in the Hsp90 and Hsp70 chaperones can be exploited for recognition and integration of substrate proteins.     

Biochemical properties of Hsp70 chaperone system from Meiothermus ruber

The guanidine-hydrochloride (Gdn-HCl) and thermally induced unfolding of Hsp70 from Meiothermus ruber (Mru.Hsp70) were analysed using tryptophan fluorescence and 8-anilino-1-naphthalenesulfonic acid (ANS) binding. The ANS binding to Mru.Hsp70 showed both the increase in fluorescence intensity and a shift in emission maximum. Analysis of the unfolding profile of Mru.Hsp70 indicated that Gdn-HCl induced unfolding of Mru.Hsp70 occurred through intermediate species. The tryptophan and ANS fluorescence emission spectra revealed that ATP induced conformational change increased the thermal stability of Mru.Hsp70. The data obtained are similar to those of Escherichia coli DnaK. The ATP-ase activity of chaperones is fundamental for their biological activity. It this paper we demonstrate that, in contrast to Thermus thermophilus, both Mru.Hsp40 and Mru.Hsp22 co-chaperones affect the ATP-ase activity of Mru.Hsp70. The use of truncated Mru.Hsp40 proteins showed that full-length Mru.Hsp40 is required for stimulation of ATP-ase activity of Mru.Hsp70. E. coli GrpE could act as nucleotide exchange factor the in thermophilic Hsp70 ATP hydrolysis reaction. However, the role of E. coli DnaJ in the M. ruber ATP cycle needs further analysis. We selected the new substrate laccA suitable for determination of refolding activity of thermophilic chaperones.     

Interactions between Hsp70 and the hydrophobic core of alpha-synuclein inhibit fibril assembly

Molecular chaperones of the heat shock protein 70 (Hsp70) family counteract protein misfolding in a variety of neurodegenerative disease models. To determine whether human Hsp70 exerts similar effects on the aggregation of alpha-synuclein (alpha-Syn), the key component of insoluble fibrils present in Parkinson's disease, we investigated alpha-Syn fibril assembly in the presence of Hsp70. We found in vitro assembly was efficiently inhibited by substoichiometric concentrations of purified Hsp70 in the absence of cofactors. Experiments using alpha-Syn deletion mutants indicated that interactions between the Hsp70 substrate binding domain and the alpha-Syn core hydrophobic region underlie assembly inhibition. This assembly process was inhibited prior to the elongation stage as we failed to detect any fibrils by electron microscopy. In addition, fluorescence polarization and binding assays suggest that Hsp70 recognizes soluble alpha-Syn species in a highly dynamic and reversible manner. Together, these results provide novel insights into how Hsp70 suppresses alpha-Syn aggregation. Furthermore, our findings suggest that this critical step in Parkinson's disease pathogenesis may be subject to modulation by a common molecular chaperone.     

The Diverse Functions of Small Heat Shock Proteins in the Proteostasis Network

The protein quality control (PQC) system maintains protein homeostasis by counteracting the accumulation of misfolded protein conformers. Substrate degradation and refolding activities executed by ATP-dependent proteases and chaperones constitute major strategies of the proteostasis network. Small heat shock proteins represent ATP-independent chaperones that bind to misfolded proteins, preventing their uncontrolled aggregation. sHsps share the conserved α-crystallin domain (ACD) and gain functional specificity through variable and largely disordered N- and C-terminal extensions (NTE, CTE). They form large, polydisperse oligomers through multiple, weak interactions between NTE/CTEs and ACD dimers. Sequence variations of sHsps and the large variability of sHsp oligomers enable sHsps to fulfill diverse tasks in the PQC network. sHsp oligomers represent inactive yet dynamic resting states that are rapidly deoligomerized and activated upon stress conditions, releasing substrate binding sites in NTEs and ACDs Bound substrates are usually isolated in large sHsp/substrate complexes. This sequestration activity of sHsps represents a third strategy of the proteostasis network. Substrate sequestration reduces the burden for other PQC components during immediate and persistent stress conditions. Sequestered substrates can be released and directed towards refolding pathways by ATP-dependent Hsp70/Hsp100 chaperones or sorted for degradation by autophagic pathways. sHsps can also maintain the dynamic state of phase-separated stress granules (SGs), which store mRNA and translation factors, by reducing the accumulation of misfolded proteins inside SGs and preventing unfolding of SG components. This ensures SG disassembly and regain of translational capacity during recovery periods.     

Characterization of two partially unfolded intermediates of the molecular chaperone DnaK at low pH

In this study, the effect of pH on the conformation and the reactivity of the Escherichia coli Hsp70 molecular chaperone DnaK was investigated using spectroscopic and chemical assays. DnaK exhibits negligible binding of the hydrophobic dye 1-anilino-naphthalene-8-sulfonate (ANS) between pH 7 to 5.0, whereas appreciable binding occurs between pH 4.5 to 4.0. The binding of ANS to a protein is diagnostic of the presence of accessible ordered hydrophobic surfaces. Such hydrophobic surfaces are often displayed by partially folded protein intermediates such as molten globules. Nucleotide inhibits 70% of the ANS binding at pH 4.5 but none of the ANS binding at pH 4.0. Proteolysis of nucleotide-free DnaK at pH 4.5 with cathepsin D yields detectable fragments (masses > 20 kDa) of the C-terminal peptide-binding domain but none of the N-terminal ATPase domain, thus the ATPase domain is preferentially targeted for proteolysis. In contrast, proteolysis of nucleotide-free DnaK at pH 4.0 with cathepsin D cuts near the linker region, yielding both functional domains. Our interpretation of these data is that incubation of DnaK at pH 4.5 produces a partially unfolded form of the ATPase domain, in which secondary structure is mainly intact, but tertiary structure is reduced. Incubation of the protein at pH 4.0 produces an intermediate in which both functional domains have collapsed and possibly separated. Nucleotide inhibits the conformational change that occurs at pH 4.5 but not at 4.0.     

Artemin as an Efficient Molecular Chaperone

Artemin is an abundant thermostable protein in Artemia encysted embryos under stress. It is considered as a stress protein, as its highly regulated expression is associated with stress resistance in this crustacea. In the present study, artemin has been shown to be a potent molecular chaperone with high efficacy. Artemin is capable of inhibiting the chemical aggregation of proteins such as carbonic anhydrase (CA) and horseradish peroxidase (HRP) at unique molar ratios of chaperone to substrates (1:40 and 1:26 for CA and HRP, respectively). Furthermore, it can also enhance refolding yield of these substrates by nearly 50%. The refolding promotion of CA is checked and verified through a sensitive fluorimetric technique. Based on these experiments, artemin showed higher chaperone activity than other chaperones. The evaluation of artemin surface using ANS showed it to be highly hydrophobic, probably resulting in its high efficacy. These results suggest that artemin can be considered a novel low molecular weight chaperone.     

N-Ethylmaleimide-modified Hsp70 inhibits protein folding.

Hsp70 molecular chaperones facilitate protein folding and translocation by binding to hydrophobic regions of nascent or unfolded proteins, thereby preventing their aggregation. N-Ethylmaleimide (NEM) inhibits the ATPase and protein translocation-stimulating activities of the yeast Hsp70 Ssa1p by modifying its three cysteine residues, which are located in its ATPase domain. NEM alters the conformation of Ssa1p and disrupts the coupling between its nucleotide- and polypeptide-binding domains. Ssa1p and the yeast DnaJ homolog Ydj1p constitute a protein folding machinery of the yeast cytosol. Using firefly luciferase as a model protein to study chaperone-dependent protein refolding, we have found that NEM also inhibits the protein folding activity of Ssa1p. Interestingly, the NEM-modified protein (NEM-Ssa1p) is a potent inhibitor of protein folding. NEM-Ssa1p can prevent the aggregation of luciferase and stimulate the ATPase activity of Ssa1p suggesting that it acts as an inhibitor by binding to nonnative forms of luciferase and by competing with them for the polypeptide binding site of Ssa1p. NEM-Ssa1p inhibits Ssa1p/Ydj1p-dependent protein refolding at different stages indicating that the chaperones bind and release nonnative forms of luciferase multiple times before folding is completed.     

Heat shock proteins 70 and 90 inhibit early stages of amyloid beta-(1-42) aggregation in vitro

Alzheimer disease is a neurological disorder that is characterized by the presence of fibrils and oligomers composed of the amyloid beta (Abeta) peptide. In models of Alzheimer disease, overexpression of molecular chaperones, specifically heat shock protein 70 (Hsp70), suppresses phenotypes related to Abeta aggregation. These observations led to the hypothesis that chaperones might interact with Abeta and block self-association. However, although biochemical evidence to support this model has been collected in other neurodegenerative systems, the interaction between chaperones and Abeta has not been similarly explored. Here, we examine the effects of Hsp70/40 and Hsp90 on Abeta aggregation in vitro. We found that recombinant Hsp70/40 and Hsp90 block Abeta self-assembly and that these chaperones are effective at substoichiometric concentrations (approximately 1:50). The anti-aggregation activity of Hsp70 can be inhibited by a nonhydrolyzable nucleotide analog and encouraged by pharmacological stimulation of its ATPase activity. Finally, we were interested in discerning what type of amyloid structures can be acted upon by these chaperones. To address this question, we added Hsp70/40 and Hsp90 to pre-formed oligomers and fibrils. Based on thioflavin T reactivity, the combination of Hsp70/40 and Hsp90 caused structural changes in oligomers but had little effect on fibrils. These results suggest that if these chaperones are present in the same cellular compartment in which Abeta is produced, Hsp70/40 and Hsp90 may suppress the early stages of self-assembly. Thus, these results are consistent with a model in which pharmacological activation of chaperones might have a favorable therapeutic effect on Alzheimer disease.     

Anion-induced folding of rabbit muscle pyruvate kinase: existence of multiple intermediate conformations at low pH

Structural and functional characteristics of rabbit muscle pyruvate kinase (PK), a tetrameric enzyme having identical subunits, were investigated under neutral as well as acidic conditions by using enzymatic activity measurements and a combination of optical methods, such as circular dichroism, fluorescence, and ANS binding. At low pH and low ionic strength, pyruvate kinase exists in a partially unfolded state (UA state) retaining half of the secondary structure and no tertiary interactions along with a strong binding to the hydrophobic dye, ANS. Addition of anions, like NaCl, KCl, and Na2SO4, to the acid-unfolded state induces refolding, resulting structural propensities similar to that of native tetramer. When anion concentration exceeds a critical limit (0.7 M KCl), a sudden loss of secondary structure and decrease in fluorescence intensity with a redshift in the emission maximum are seen which may be due to the aggregation of the protein, probably due to the intermolecular association. The anion-refolded state is more stable than the UA state, and its stability is nearly equal to that of native protein toward chemical-induced unfolding by Gu-HCl and urea. Moreover, at low concentrations, Gu-HCl behaves like an anion, by inducing refolding of the acid-unfolded state with structural features equivalent to that of native molecule. These observations support a model of protein folding where certain conformations of low free energy prevail and are populated under non-native conditions with different stability.     

Heat shock proteins, substrate specificity and modulation of function

Hsp70 is a universally conserved essential protein chaperone. In addition to its roles in many cellular process, Hsp70 protects cells from stress by binding partially unfolded proteins. Therefore, Hsp70 prevents protein aggregation and prion formation. Prions are infectious agents and are responsible for several fatal neurodegenerative diseases. Eukaryotic cells have several cytosolic Hsp70 isoforms, some constitutively expressed (Hsc70s), and others expressed only when cells are exposed to stress (Hsp70s). To determine which factors conferred functional specificity, we constructed hybrid Hsc/Hsp chaperones. All hybrids supported growth except those that contained the ATPase domain derived from inducible Hsp70. Thus, regulation of peptide binding by ATP hydrolysis must differ significantly between Hsc- and Hsp70 isoforms. In this work, nucleotide and peptide binding domain communication of Hsp70 proteins during their interaction with nucleotides and peptide substrates were investigated in vitro by using hybrid constructs.     

The ClpX heat-shock protein of Escherichia coli, the ATP-dependent substrate specificity component of the ClpP-ClpX protease, is a novel molecular chaperone.

All major classes of protein chaperones, including DnaK (the Hsp70 eukaryotic equivalent) and GroEL (the Hsp60 eukaryotic equivalent) have been found in Escherichia coli. Molecular chaperones enhance the yields of correctly folded polypeptides by preventing aggregation and even by disaggregating certain protein aggregates. Previously, we identified the ClpX heat-shock protein of E. coli because it enables the ClpP catalytic protease to degrade the bacteriophage lambda O replication protein. Here we report that ClpX alone possesses all the properties expected of a molecular chaperone protein. Specifically, it can protect the lambda O protein from heat-induced aggregation, disaggregate preformed lambda O aggregates, and even promote efficient binding of lambda O to its DNA recognition sequence. A lambda O-ClpX specific protein-protein interaction can be detected either by a modified ELISA assay or through the stimulation of ClpX's weak ATPase activity by lambda O. Unlike the behaviour of the major DnaK and GroEL chaperones, ClpX requires the presence of ATP or its non-hydrolysable analogue ATP-gamma-S for efficient interaction with other proteins including the protection of lambda O from aggregation. However, ClpX's ability to disaggregate lambda O aggregates requires hydrolysable ATP. We propose that the ClpX protein is a bona fide chaperone, whose biological role includes the maintenance of certain polypeptides in a form competent for proteolysis by the ClpP protease. Furthermore, our results suggest that the ClpX protein also performs typical chaperone protein functions independent of ClpP.     

Folding or holding?—Hsp70 and Hsp90 chaperoning of misfolded proteins in neurodegenerative disease

The toxic accumulation of misfolded proteins as inclusions, fibrils, or aggregates is a hallmark of many neurodegenerative diseases. However, how molecular chaperones, such as heat shock protein 70 kDa (Hsp70) and heat shock protein 90 kDa (Hsp90), defend cells against the accumulation of misfolded proteins remains unclear. The ATP-dependent foldase function of both Hsp70 and Hsp90 actively transitions misfolded proteins back to their native conformation. By contrast, the ATP-independent holdase function of Hsp70 and Hsp90 prevents the accumulation of misfolded proteins. Foldase and holdase functions can protect against the toxicity associated with protein misfolding, yet we are only beginning to understand the mechanisms through which they modulate neurodegeneration. This review compares recent structural findings regarding the binding of Hsp90 to misfolded and intrinsically disordered proteins, such as tau, α-synuclein, and Tar DNA-binding protein 43. We propose that Hsp90 and Hsp70 interact with these proteins through an extended and dynamic interface that spans the surface of multiple domains of the chaperone proteins. This contrasts with many other Hsp90–client protein interactions for which only a single bound conformation of Hsp90 is proposed. The dynamic nature of these multidomain interactions allows for polymorphic binding of multiple conformations to vast regions of Hsp90. The holdase functions of Hsp70 and Hsp90 may thus allow neuronal cells to modulate misfolded proteins more efficiently by reducing the long-term ATP running costs of the chaperone budget. However, it remains unclear whether holdase functions protect cells by preventing aggregate formation or can increase neurotoxicity by inadvertently stabilizing deleterious oligomers.