Folding-like-refolding of heat-denatured MDH using unpurified ClpB and DnaKJE

The Escherichia coli heat-shock protein ClpB can efficiently solubilize protein aggregates and refold them into active proteins in cooperation with the DnaK–DnaJ–GrpE chaperone (DnaKJE) system. However, the application of this bichaperone system at a large-scale was restricted because of the difficulties and high cost to express and purify each of these molecular chaperones. In this study, we constructed a plasmid encoding ClpB with a 6xHis-tag at its C-terminus (His-ClpB) to facilitate its purification through Immobilized Metal Affinity Chromatography (IMAC). A different plasmid capable of expressing the DnaKJE was used to obtain a cell extract containing unpurified DnaKJE. The effect of purified His-ClpB and unpurified DnaKJE on the refolding of heat-denatured malate dehydrogenase (MDH) was investigated, and proved to be highly efficient for MDH refolding. Furthermore, the use of both unpurified His-ClpB and DnaKJE available in the cell extract enabled highly successful refolding of the heat-denatured MDH with efficacy comparable to the case where the purified His-ClpB was used. To the best of our knowledge, this is the first attempt to apply a refolding cocktail comprising unpurified bichaperone system to the refolding of a heat-denatured protein, providing a practical and economically viable way of implementing a large-scale folding-like-refolding strategy.     

Trigger factor-dependent refolding of bacterial luciferases in Escherichia coli: Kinetics, efficiency, and effect of bichaperone system

The main parameters of the trigger-factor-dependent refolding process of thermally inactivated bacterial luciferases were determined. It has been demonstrated that TF-dependent refolding is less efficient and more time consuming than DnaKJE-dependent refolding. An increase in the cellular concentration of TF was found to result in a dramatic decrease in the maximum level of refolding of thermally inactivated bacterial luciferases. Additionally, the efficiency of TF-dependent refolding was shown to decrease with an increase in the thermal stability of the substrate, that is, the level of TF-dependent refolding is significantly higher for thermolabile luciferases than for thermostable luciferases. For example, the maximum TF-dependent refolding level was determined as 30–40% for thermolabile luciferases from Aliivibrio fischeri and Photobacterium leiognathi, 10% in the case of luciferase from Vibrio harveyi, which is characterized by an average thermal stability, and finally 0.5% in the case of highly stable at high temperatures luciferase from Photorhabdus luminescens. An effect of the DnaKJE-ClpB bichaperone system on the efficiency of TF-dependent refolding was investigated. The ClpB component of the bichaperone system was shown to negatively affect the process efficiency, that is, TF-dependent refolding of bacterial luciferases was found to be far more efficient in E. coli clpB::kan cell strains than in E. coli clpB⁺ strains.     

Mutation <Emphasis Type="Italic">clp</Emphasis>A::<Emphasis Type="Italic">kan</Emphasis> of the gene for an Hsp100 family chaperone impairs the DnaK-dependent refolding of proteins in <Emphasis Type="Italic">Escherichia coli</Emphasis>

The rate and level of DnaK-dependent refolding of heat-inactivated Vibrio fischeri luciferase in the clp A mutant (clp A:: kan) were considerably lower then in wild-type cells. The decline in refolding level progressed with increasing heat inactivation time. A mutation of clp P had no influence on the kinetics and level of luciferase refolding. Approximately equal amounts of the DnaKJE chaperone were synthesized upon heat shock induction in E. coli clp A + and E. coli clpA::kan cells. It was assumed that, like homologous chaperone ClpB, ClpA is involved in disaggregation of denatured proteins, increasing the refolding efficiency. This in vivo phenomenon occurred only upon a prolonged incubation of cells at a higher temperature, which led to the formation of large protein aggregates that were poorly refoldable by the DnaKJE system.     

The amino-terminal domain of ClpB supports binding to strongly aggregated proteins

Bacterial heat-shock proteins, ClpB and DnaK form a bichaperone system that efficiently reactivates aggregated proteins. ClpB undergoes nucleotide-dependent self-association and forms ring-shaped oligomers. The ClpB-assisted dissociation of protein aggregates is linked to translocation of substrates through the central channel in the oligomeric ClpB. Events preceding the translocation step, such as recognition of aggregates by ClpB, have not yet been explored, and the location of the aggregate-binding site in ClpB has been under discussion. We investigated the reactivation of aggregated glucose-6-phosphate dehydrogenase (G6PDH) by ClpB and its N-terminally truncated variant ClpBDeltaN in the presence of DnaK, DnaJ, and GrpE. We found that the chaperone activity of ClpBDeltaN becomes significantly lower than that of the full-length ClpB as the size of G6PDH aggregates increases. Using a "substrate trap" variant of ClpB with mutations of Walker B motifs in both ATP-binding modules (E279Q/E678Q), we demonstrated that ClpBDeltaN binds to G6PDH aggregates with a significantly lower affinity than the full-length ClpB. Moreover, we identified two conserved acidic residues at the surface of the N-terminal domain of ClpB that support binding to G6PDH aggregates. Those N-terminal residues (Asp-103, Glu-109) contribute as much substrate-binding capability to ClpB as the conserved Tyr located at the entrance to the ClpB channel. In summary, we provided evidence for an essential role of the N-terminal domain of ClpB in recognition and binding strongly aggregated proteins.     

ClpB cooperates with DnaK, DnaJ, and GrpE in suppressing protein aggregation. A novel multi-chaperone system from Escherichia coli.

ClpB is a heat-shock protein from Escherichia coli with an unknown function. We studied a possible molecular chaperone activity of ClpB in vitro. Firefly luciferase was denatured in urea and then diluted into the refolding buffer (in the presence of 5 mM ATP and 0.1 mg/ml bovine serum albumin). Spontaneous reactivation of luciferase was very weak (less than 0.02% of the native activity) because of extensive aggregation. Conventional chaperone systems (GroEL/GroES and DnaK/DnaJ/GrpE) or ClpB alone did not reactivate luciferase under those conditions. However, ClpB together with DnaK/DnaJ/GrpE greatly enhanced the luciferase activity regain (up to 57% of native activity) by suppressing luciferase aggregation. This coordinated function of ClpB and DnaK/DnaJ/GrpE required ATP hydrolysis, although the ClpB ATPase was not activated by native or denatured luciferase. When the chaperones were added to the luciferase refolding solutions after 5-25 min of refolding, ClpB and DnaK/DnaJ/GrpE recovered the luciferase activity from preformed aggregates. Thus, we have identified a novel multi-chaperone system from E. coli, which is analogous to the Hsp104/Ssa1/Ydj1 system from yeast. ClpB is the only known bacterial Hsp100 protein capable of cooperating with other heat-shock proteins in suppressing and reversing protein aggregation.     

Interaction of the N-terminal domain of Escherichia coli heat-shock protein ClpB and protein aggregates during chaperone activity

The Escherichia coli heat-shock protein ClpB reactivates protein aggregates in cooperation with the DnaK chaperone system. The ClpB N-terminal domain plays an important role in the chaperone activity, but its mechanism remains unknown. In this study, we investigated the effect of the ClpB N-terminal domain on malate dehydrogenase (MDH) refolding. ClpB reduced the yield of MDH refolding by a strong interaction with the intermediate. However, the refolding kinetics was not affected by deletion of the ClpB N-terminal domain (ClpBDeltaN), indicating that MDH refolding was affected by interaction with the N-terminal domain. In addition, the MDH refolding yield increased 50% in the presence of the ClpB N-terminal fragment (ClpBN). Fluorescence polarization analysis showed that this chaperone-like activity is explained best by a weak interaction between ClpBN and the reversible aggregate of MDH. The dissociation constant of ClpBN and the reversible aggregate was estimated as 45 muM from the calculation of the refolding kinetics. Amino acid substitutions at Leu 97 and Leu 110 on the ClpBN surface reduced the chaperone-like activity and the affinity to the substrate. In addition, these residues are involved in stimulation of ATPase activity in ClpB. Thus, Leu 97 and Leu 110 are responsible for the substrate recognition and the regulation of ATP-induced ClpB conformational change.     

Effects of E. coli chaperones on the solubility of human receptors in an in vitro expression system

The implementation of efficient technologies for the production of recombinant mammalian membrane receptors is an outstanding challenge in understanding receptor-ligand actions and the development of therapeutic antibodies. In order to improve the solubility of recombinant extracellular domains of human membrane receptors expressed in Escherichia coli, proteins were synthesized by an E. coli in vitro translation system supplemented with bacterial molecular chaperones, such as GroEL-GroES (GroEL/ES), Trigger factor (TF), a DnaK-DnaJ-GrpE chaperone system (DnaKJE), and/or a heat shock protein Hsp100, ClpB. The following three proteins that are prone to aggregation were examined: the extracellular domain (ECD) or the second immunoglobulin-like domain (IgII) of the human neurotrophin receptor TrkC (TrkC-ECD and TrkC-IgII), and the C-type lectin carbohydrate recognition domain of the human asialoglycoprotein receptor (ASGPR HI CRD). The cooperative chaperone system including GroEL/ES, DnaKJE and ClpB had a marked effect on the solubility of TrkC-ECD and TrkC-IgII, and the GroEL/ES-DnaKJE-TF chaperone system was more effective for TrkC-IgII. The GroEL/ES-DnaKJE-TF chaperone network increased the yield of soluble ASGPR HI CRD. The present findings demonstrate that E. coli molecular chaperones are useful in improving the yield of soluble recombinant extracellular domains of human membrane receptors in an E. coli expression system.     

Refolding of substrates bound to small Hsps relies on a disaggregation reaction mediated most efficiently by ClpB/DnaK

Small heat shock proteins (sHsps) are ubiquitous molecular chaperones that bind denatured proteins in vitro, thereby facilitating their subsequent refolding by ATP-dependent chaperones. The mechanistic basis of this refolding process is poorly defined. We demonstrate that substrates complexed to sHsps from various sources are not released spontaneously. Dissociation and refolding of sHsp bound substrates relies on a disaggregation reaction mediated by the DnaK system, or, more efficiently, by ClpB/DnaK. While the DnaK system alone works for small, soluble sHsp/substrate complexes, ClpB/DnaK-mediated protein refolding is fastest for large, insoluble protein aggregates with incorporated sHsps. Such conditions reflect the situation in vivo, where sHsps are usually associated with insoluble proteins during heat stress. We therefore propose that sHsp function in cellular protein quality control is to promote rapid resolubilization of aggregated proteins, formed upon severe heat stress, by DnaK or ClpB/DnaK.     

Refolding of lactate dehydrogenase by zeolite beta

We used zeolite beta as an adsorbing matrix to refold recombinant lactate dehydrogenase (LDH) protein collected as an insoluble aggregate from a bacterial expression system. The adsorption isotherm revealed that 1 g of zeolite adsorbed 200 mg of denatured LDH solubilized with a buffer containing 6 M of guanidine hydrochloride. The pH of the buffer had little effect on the adsorption, but this property was abolished by preincubation of the zeolite with polyethylene glycol (PEG) in a weight ratio of 1:10. These data suggest that the adsorption of LDH depends on the hydrophobicity of the zeolite surface, and that the adsorption of PEG to zeolite is sufficient to release LDH from its surface. LDH was thus released by refolding buffer containing PEG and arginine, and soluble LDH was obtained in its active enzymatic form. The addition of arginine dramatically increased the yield of LDH in a dose‐dependent manner. The overall refolding efficiency was optimized to 35%. © 2009 American Institute of Chemical Engineers Biotechnol. Prog., 2009     

Disulfide–bridging PEGylation during refolding for the more efficient production of modified proteins

Proteins that are modified by chemical conjugation require at least two separate purification processes. First the bulk protein is purified, and then after chemical conjugation, a second purification process is required to obtain the modified protein. In an effort to develop new enabling technologies to integrate bioprocessing and protein modification, we describe the use of disulfide‐bridging conjugation to conduct PEGylation during protein refolding. Preliminary experiments using a PEG‐mono‐sulfone reagent with partially unfolded leptin and unfolded RNAse T1 indicated that the cysteine thiols underwent disulfide‐bridging conjugation to give the PEGylated proteins. Interferon‐β1b (IFN‐β1b) was then expressed in E.coli as inclusion bodies and found to undergo disulfide bridging‐conjugation during refolding. The PEG‐IFN‐β1b was isolated by ion‐exchange chromatography and displayed in vitro biological activity. In the absence of the PEGylation reagent, IFN‐β1b refolding was less efficient and yielded protein aggregates. No PEGylation was observed if the cysteines on IFN‐β1b were first modified with iodoacetamide prior to refolding. Our results demonstrate that the simultaneous refolding and disulfide bridging PEGylation of proteins could be a useful strategy in the development of affordable modified protein therapeutics.     

Polyethylene glycol enhanced refolding of bovine carbonic anhydrase B. Reaction stoichiometry and refolding model.

Polyethylene glycol (PEG) inhibited aggregation during refolding of bovine carbonic anhydrase B (CAB) through the formation of a nonassociating PEG-intermediate complex. Stoichiometric concentrations of PEG were required for complete recovery of active protein during refolding at aggregating conditions. For example, a PEG (Mr = 3350) to CAB molar ratio ([PEG]/[CAB]) of 2 was sufficient to inhibit aggregation during refolding at 1.0 mg/ml (33.3 microM) protein and 0.5 M guanidine hydrochloride. In addition, the PEG concentration required for enhancement was dependent upon the molecular weight and only molecular weights between 1000 and 8000 were effective in inhibiting aggregation. In the presence of PEG, the rate of refolding was the same as that observed for refolding without the formation of associated species. Refolding in the presence of PEG resulted in the rapid formation of a PEG complex with the molten globule first intermediate, and this PEG-intermediate complex did not aggregate. The CAB refolding kinetics in the presence of PEG were determined and used to develop a model of the PEG enhanced refolding pathway. The mathematical model was validated by independent activity measurements of CAB refolding. This model predicted that PEG enhanced refolding of CAB occurred by a specific interaction of PEG with the molten globule first intermediate to form a nonassociating complex which continued to fold at the same rate as the first intermediate. The predicted pathway and binding properties of PEG indicate that PEG enhanced refolding may be analogous to chaperonin mediated protein folding.     

Saccharomyces cerevisiae Hsp104 enhances the chaperone capacity of human cells and inhibits heat stress-induced proapoptotic signaling

Hsp104, the most potent thermotolerance factor in Saccharomyces cerevisiae, is an unusual molecular chaperone that is associated with the dispersal of aggregated, non-native proteins in vivo and in vitro. The close cooperation between Hsp100 oligomeric disaggregases and specific Hsp70 chaperone/cochaperone systems to refold and reactivate heat-damaged proteins has been dubbed a "bichaperone network". Interestingly, animal genomes do not encode a Hsp104 ortholog. To investigate the biochemical and biological consequences of introducing into human cells a stress tolerance factor that has protein refolding capabilities distinct from those already present, Hsp104 was expressed as a transgene in a human leukemic T-cell line (PEER). Hsp104 inhibited heat-shock-induced loss of viability in PEER cells, and this action correlated with reduced procaspase-3 cleavage but not with reduced c-Jun N-terminal kinase phosphorylation. Hsp104 cooperated with endogenous human Hsp70 and Hsc70 molecular chaperones and their J-domain-containing cochaperones Hdj1 and Hdj2 to produce a functional hybrid bichaperone network capable of refolding aggregated luciferase. We also established that Hsp104 shuttles across the nuclear envelope and enhances the chaperoning capacity of both the cytoplasm and nucleoplasm of intact cells. Our results establish the fundamental properties of protein disaggregase function in human cells with implications for the use of Hsp104 or related proteins as therapeutic agents in diseases associated with protein aggregation.     

Mechanism of pH‐sensitive polymer‐assisted protein refolding and its application in TGF‐β1 and KGF‐2

Refolding of proteins at high concentrations often results in non‐productive aggregation. This study, through a unique combination of spectroscopic and chromatographic analyzes, provides biomolecular evidence to demonstrate the ability of Eudragit S‐100, a pH‐responsive polymer, to enhance refolding of denatured‐reduced lysozyme at high concentrations. The addition of Eudragit in the refolding buffer significantly increases lysozyme refolding yield to 75%, when dilution refolding was conducted at 1 mg/mL lysozyme. This study shows evidence of an electrostatic interaction between oppositely charged lysozyme and the Eudragit polymer during refolding. This ionic complexing of Eudragit and lysozyme appears to shield exposed hydrophobic residues of the lysozyme refolding intermediates, thus minimizing hydrophobic‐driven aggregation of the molecules. Importantly, results from this study show that the Eudragit‐lysozyme bioconjugation does not compromise refolded protein structure, and that the polymer can be readily dissociated from the protein by ion exchange chromatography. The strategy was also applied to refolding of TGF‐β1 and KGF‐2. © 2009 American Institute of Chemical Engineers Biotechnol. Prog. 2009     

A chaperone network for the resolubilization of protein aggregates: direct interaction of ClpB and DnaK

The molecular chaperones ClpB (Hsp104) and DnaK (Hsp70) co-operate in the ATP-dependent resolubilization of aggregated proteins. A sequential mechanism has been proposed for this reaction; however, the mechanism and the functional interplay between both chaperones remain poorly defined. Here, we show for the first time that complex formation of ClpB and DnaK can be detected by using various types of affinity chromatography methods. The finding that the DnaK chaperone of Escherichia coli is not co-operating with ClpB from Thermus thermophilus further strengthens the specificity of this complex. The affinity of the complex is weak and interaction between both chaperones is nucleotide-dependent. The presence of ADP, which is shown to cause dissociation of ClpB(Tth), as well as ClpB deletion mutants incapable of oligomer formation prevent ClpB-DnaK complex formation. The experiments presented indicate a correlation between the oligomeric state of ClpB and its ability to interact with DnaK. The chaperone complex described here might facilitate transfer of intermediates between ClpB and DnaK during refolding of substrates from aggregates.     

Connexin45 directly binds to ZO-1 and localizes to the tight junction region in epithelial MDCK cells

The molecular chaperone protein Hsp78, a member of the Clp/Hsp100 family localized in the mitochondria of Saccharomyces cerevisiae, is required for maintenance of mitochondrial functions under heat stress. To characterize the biochemical mechanisms of Hsp78 function, Hsp78 was purified to homogeneity and its role in the reactivation of chemically and heat-denatured substrate protein was analyzed in vitro. Hsp78 alone was not able to mediate reactivation of firefly luciferase. Rather, efficient refolding was dependent on the simultaneous presence of Hsp78 and the mitochondrial Hsp70 machinery, composed of Ssc1p/Mdj1p/Mge1p. Bacterial DnaK/DnaJ/GrpE, which cooperates with the Hsp78 homolog, ClpB in Escherichia coli, could not substitute for the mitochondrial Hsp70 system. However, efficient Hsp78-dependent refolding of luciferase was observed if DnaK was replaced by Ssc1p in these experiments, suggesting a specific functional interaction of both chaperone proteins. These findings establish the cooperation of Hsp78 with the Hsp70 machinery in the refolding of heat-inactivated proteins and demonstrate a conserved mode of action of ClpB homologs.     

The N terminus of ClpB from Thermus thermophilus is not essential for the chaperone activity

ClpB from Thermus thermophilus belongs to the Clp/Hsp100 protein family and reactivates protein aggregates in cooperation with the DnaK chaperone system. The mechanism of protein reactivation and interaction with the DnaK system remains unclear. ClpB possesses two nucleotide binding domains, which are essential for function and show a complex allosteric behavior. The role of the N-terminal domain that precedes the first nucleotide binding domain is largely unknown. We purified and characterized an N-terminal shortened ClpB variant (ClpBDeltaN; amino acids 140-854), which remained active in refolding assays with three different substrate proteins. In addition the N-terminal truncation did not significantly change the nucleotide binding affinities, the nucleotide-dependent oligomerization, and the allosteric behavior of the protein. In contrast casein binding and stimulation of the ATPase activity by kappa-casein were affected. These results suggest that the N-terminal domain is not essential for the chaperone function, does not influence the binding of nucleotides, and is not involved in the formation of intermolecular contacts. It contributes to the casein binding site of ClpB, but other substrate proteins do not necessarily interact with the N terminus. This indicates a substantial difference in the binding mode of kappa-casein that is often used as model substrate for ClpB and other possibly more suitable substrate proteins.     

ClpV, a unique Hsp100/Clp member of pathogenic proteobacteria

Hsp100/Clp proteins are key players in the protein quality control network of prokaryotic cells and function in the degradation and refolding of misfolded or aggregated proteins. Here we report the identification of a new class of Hsp100/Clp proteins, termed ClpV (virulent strain), that are present in bacteria interacting with eukaryotic cells, including human pathogens. The ClpV proteins are most similar to ClpB proteins within the Hsp100/Clp family, but cluster in a separate phylogenetic tree with a remarkable distance to ClpB. ClpV representatives from Salmonella typhimurium and enteropathogenic Escherichia coli form oligomeric assemblies and display ATP hydrolysis rates comparable to ClpB. However, unlike ClpB, both ClpV proteins failed to solubilize aggregated proteins. This lack of disaggregation activity correlated with the inability of ClpB model substrates to stimulate the ATPase activity of ClpV proteins, indicating differences in substrate selection. Furthermore, we show that clpV genes are generally organized in a conserved gene cluster, encoding a potential secretion system, and we demonstrate that increased levels of a dominant negative variant of either S. typhimurium or Yersinia pseudotuberculosis ClpV strongly reduce the ability of these pathogenic bacteria to invade epithelial cells. We propose a role of this novel and unique class of AAA+ proteins in bacteria-host cell interactions.     

Flexible connection of the N‐terminal domain in ClpB modulates substrate binding and the aggregate reactivation efficiency

ClpB reactivates aggregated proteins in cooperation with DnaK/J. The ClpB monomer contains two nucleotide‐binding domains (D1, D2), a coiled‐coil domain, and an N‐terminal domain attached to D1 with a 17‐residue‐long unstructured linker containing a Gly‐Gly motif. The ClpB‐mediated protein disaggregation is linked to translocation of substrates through the central channel in the hexameric ClpB, but the events preceding the translocation are poorly understood. The N‐terminal domains form a ring surrounding the entrance to the channel and contribute to the aggregate binding. It was suggested that the N‐terminal domain's mobility that is maintained by the unstructured linker might control the efficiency of aggregate reactivation. We produced seven variants of ClpB with modified sequence of the N‐terminal linker. To increase the linker's conformational flexibility, we inserted up to four Gly next to the GG motif. To decrease the linker's flexibility, we deleted the GG motif and converted it into GP and PP. We found that none of the linker modifications inhibited the basal ClpB ATPase activity or its capability to form oligomers. However, the modified linker ClpB variants showed lower reactivation rates for aggregated glucose‐6‐phosphate dehydrogenase and firefly luciferase and a lower aggregate‐binding efficiency than wt ClpB. We conclude that the linker does not merely connect the N‐terminal domain, but it supports the chaperone activity of ClpB by contributing to the efficiency of aggregate binding and disaggregation. Moreover, our results suggest that selective pressure on the linker sequence may be crucial for maintaining the optimal efficiency of aggregate reactivation by ClpB. Proteins 2012; © 2012 Wiley Periodicals, Inc.     

Examination of polypeptide substrate specificity for Escherichia coli ClpB

Escherichia coli ClpB is a molecular chaperone that belongs to the Clp/Hsp100 family of AAA+ proteins. ClpB is able to form a hexameric ring structure to catalyze protein disaggregation with the assistance of the DnaK chaperone system. Our knowledge of the mechanism of how ClpB recognizes its substrates is still limited. In this study, we have quantitatively investigated ClpB binding to a number of unstructured polypeptides using steady‐state anisotropy titrations. To precisely determine the binding affinity for the interaction between ClpB hexamers and polypeptide substrates the titration data were subjected to global non‐linear least squares analysis incorporating the dynamic equilibrium of ClpB assembly. Our results show that ClpB hexamers bind tightly to unstructured polypeptides with binding affinities in the range of ～3–16 nM. ClpB exhibits a modest preference of binding to Peptide B1 with a binding affinity of (1.7 ± 0.2) nM. Interestingly, we found that ClpB binds to an unstructured polypeptide substrate of 40 and 50 amino acids containing the SsrA sequence at the C‐terminus with an affinity of (12 ± 3) nM and (4 ± 2) nM, respectively. Whereas, ClpB binds the 11‐amino acid SsrA sequence with an affinity of (140 ± 20) nM, which is significantly weaker than other polypeptide substrates that we tested here. We hypothesize that ClpB, like ClpA, requires substrates with a minimum length for optimal binding. Finally, we present evidence showing that multiple ClpB hexamers are involved in binding to polypeptides ≥152 amino acids. Proteins 2015; 83:117–134. © 2014 Wiley Periodicals, Inc.     

Chaperone networks in protein disaggregation and prion propagation

The oligomeric AAA+ chaperones Escherichia coli ClpB and Saccharomyces cerevisiae Hsp104 cooperate with cognate Hsp70/Hsp40 chaperone machineries in the reactivation of aggregated proteins in E. coli and S. cerevisiae. In addition, Hsp104 and Hsp70/Hsp40 are crucial for the maintenance of prion aggregates in yeast cells. While the bichaperone system efficiently solubilizes stress-generated amorphous aggregates, structurally highly ordered prion fibrils are only partially processed, resulting in the generation of fragmented prion seeds that can be transmitted to daughter cells for stable inheritance. Here, we describe and discuss the most recent mechanistic findings on yeast Hsp104 and Hsp70/Hsp40 cooperation in the remodeling of both types of aggregates, emphasizing similarities in the mechanism but also differences in the sensitivities towards chaperone activities.