Cooperative action of Escherichia coli ClpB protein and DnaK chaperone in the activation of a replication initiation protein

The Escherichia coli molecular chaperone protein ClpB is a member of the highly conserved Hsp100/Clp protein family. Previous studies have shown that the ClpB protein is needed for bacterial thermotolerance. Purified ClpB protein has been shown to reactivate chemically and heat-denatured proteins. In this work we demonstrate that the combined action of ClpB and the DnaK, DnaJ, and GrpE chaperones leads to the activation of DNA replication of the broad-host-range plasmid RK2. In contrast, ClpB is not needed for the activation of the oriC-dependent replication of E. coli. Using purified protein components we show that the ClpB/DnaK/DnaJ/GrpE synergistic action activates the plasmid RK2 replication initiation protein TrfA by converting inactive dimers to an active monomer form. In contrast, Hsp78/Ssc1/Mdj1/Mge1, the corresponding protein system from yeast mitochondria, cannot activate the TrfA replication protein. Our results demonstrate for the first time that the ClpB/DnaK/DnaJ/GrpE system is involved in protein monomerization and in the activation of a DNA replication factor.     

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.     

Heat shock protein-mediated disassembly of nucleoprotein structures is required for the initiation of bacteriophage lambda DNA replication

Three Escherichia coli heat shock proteins, DnaJ, DnaK, and GrpE, are required for replication of the bacteriophage lambda chromosome in vivo. We show that the GrpE heat shock protein is not required for initiation of lambda DNA replication in vitro when the concentration of DnaK is sufficiently high. GrpE does, however, greatly potentiate the action of DnaK in the initiation process when the DnaK concentration is reduced to a subsaturating level. We demonstrate in the accompanying articles (Alfano, C. and McMacken, R. (1989) J. Biol. Chem. 264, 10699-10708; Dodson, M., McMacken, R., and Echols, H. (1989) J. Biol. Chem. 264, 10719-10725) that DnaJ and DnaK bind to prepriming nucleoprotein structures that are assembled at the lambda replication origin (ori lambda). Binding of DnaJ and DnaK completes the ordered assembly of an ori lambda initiation complex that also contains the lambda O and P initiators and the E. coli DnaB helicase. With the addition of ATP, the DnaJ and DnaK heat shock proteins mediate the partial disassembly of the initiation complex, and the P and DnaJ proteins are largely removed from the template. Concomitantly, on supercoiled ori lambda plasmid templates, the intrinsic helicase activity of DnaB is activated and DnaB initiates localized unwinding of the DNA duplex, thereby preparing the template for priming and DNA chain elongation. We infer from our results that DnaK and DnaJ function in normal E. coli metabolism to promote ATP-dependent protein unfolding and disassembly reactions. We also provide evidence that neither the lambda O and P initiators nor the E. coli DnaJ and DnaK heat shock proteins play a direct role in the propagation of lambda replication forks in vitro.     

Successive and synergistic action of the Hsp70 and Hsp100 chaperones in protein disaggregation

Proteins belonging to the B-subtype of the Hsp100/Clp chaperone family execute a crucial role in cellular thermotolerance. They cooperate with the Hsp70 chaperones in reactivation of thermally aggregated protein substrates. We investigated the initial events of the disaggregation reaction in real time using denatured, aggregated green fluorescent protein (GFP) as a substrate. Bacterial Hsp70 (DnaK), its co-chaperones (DnaJ and GrpE), and Hsp100 (ClpB) were incubated with aggregated GFP, and the increase in GFP fluorescence was monitored. Incubation of aggregated GFP with DnaK/DnaJ/GrpE but not with ClpB resulted in the rapid initiation of the disaggregation reaction. Under the same conditions a complex between DnaK, DnaJ, and GFP, but not ClpB, was formed as demonstrated by sedimentation analysis and light scattering experiments. Chaperone-dependent disaggregation of chemically denatured aggregated luciferase showed that, similar to GFP disaggregation, incubation with Hsp70 results in the rapid start of the reactivation reaction. For both aggregated GFP and luciferase, incubation with Hsp70 chaperones changes the initial rate but not the overall efficiency or rate of the refolding reaction. Our results clearly demonstrate that the interaction of DnaK and its co-chaperones with aggregated substrate is the rate-limiting reaction at the initial steps of disaggregation.     

Interaction of the DnaK and DnaJ chaperone system with a native substrate,P1 RepA

DnaK, the Hsp70 chaperone of Escherichia coli interacts with protein substrates in an ATP-dependent manner, in conjunction with DnaJ and GrpE co-chaperones, to carry out protein folding, protein remodeling, and assembly and disassembly of multisubunit protein complexes. To understand how DnaJ targets specific proteins for recognition by the DnaK chaperone system, we investigated the interaction of DnaJ and DnaK with a known natural substrate, bacteriophage P1 RepA protein. By characterizing RepA deletion derivatives, we found that DnaJ interacts with a region of RepA located between amino acids 180 and 200 of the 286-amino acid protein. A peptide corresponding to amino acids 180-195 inhibited the interaction of RepA and DnaJ. Two site-directed RepA mutants with alanine substitutions in this region were about 4-fold less efficiently activated for oriP1 DNA binding by DnaJ and DnaK than wild type RepA. We also identified by deletion analysis a site in RepA, in the region of amino acids 35-49, which interacts with DnaK. An alanine substitution mutant in amino acids 36-39 was constructed and found defective in activation by DnaJ and DnaK. Taken together the results suggest that DnaJ and DnaK interact with separate sites on RepA.     

In vivo and in vitro complementation study comparing the function of DnaK chaperone systems from halophilic lactic acid bacterium Tetragenococcus halophilus and Escherichia coli

In this study, we characterized the DnaK chaperone system from Tetragenococcus halophilus, a halophilic lactic acid bacterium. An in vivo complementation test showed that under heat stress conditions, T. halophilus DnaK did not rescue the growth of the Escherichia coli dnaK deletion mutant, whereas T. halophilus DnaJ and GrpE complemented the corresponding mutations of E. coli. Purified T. halophilus DnaK showed intrinsic weak ATPase activity and holding chaperone activity in vitro, but T. halophilus DnaK did not cooperate with the purified DnaJ and GrpE from either T. halophilus or E. coli in ATP hydrolysis or luciferase-refolding reactions under the conditions tested. E. coli DnaK, however, cross-reacted with those from both bacteria. This difference in the cooperation with DnaJ and GrpE appears to result in an inability of T. halophilus DnaK to replace the in vivo function of the DnaK chaperone of E. coli.     

Regulation of ATPase and chaperone cycle of DnaK from Thermus thermophilus by the nucleotide exchange factor GrpE

The nucleotide binding and release cycle of the molecular chaperone DnaK is regulated by the accessory proteins GrpE and DnaJ, also called co-chaperones. The concerted action of the nucleotide exchange factor GrpE and the ATPase-stimulating factor DnaJ determines the ratio of the two nucleotide states of DnaK, which differ in their mode of interaction with unfolded proteins. In the Escherichia coli system, the stimulation by these two antagonists is comparable in magnitude, resulting in a balance of the two nucleotide states of DnaK(Eco) in the absence and the presence of co-chaperones.The regulation of the DnaK chaperone system from Thermus thermophilus is apparently substantially different. Here, DnaJ does not stimulate the DnaK-mediated ATP hydrolysis and thus does not appear to act as an antagonist of the nucleotide exchange factor GrpE(Tth). This raises the question of whether T. thermophilus GrpE stimulates nucleotide exchange to a smaller degree as compared to the E. coli system and how the corresponding rates relate to intrinsic ATPase and ATP binding as well as luciferase refolding kinetics of T. thermophilus DnaK.We determined dissociation constants as well as kinetic constants that describe the interactions between the T. thermophilus molecular chaperone DnaK, its nucleotide exchange factor GrpE and the fluorescent ADP analogue N8-(4-N'-methylanthraniloylaminobutyl)-8-aminoadenosine-5'-diphosphate by isothermal equilibrium titration calorimetry and stopped-flow kinetic experiments and investigated the influence of T. thermophilus DnaJ on the DnaK nucleotide cycle.The interaction of GrpE with the DnaK.ADP complex versus nucleotide-free DnaK can be described by a simple equilibrium system, where GrpE reduces the affinity of DnaK for ADP by a factor of about 10. Kinetic experiments indicate that the maximal acceleration of nucleotide release by GrpE is 80,000-fold at a saturating GrpE concentration.Our experiments show that in T. thermophilus, although the thermophilic DnaK system displays no stimulation of the DnaK-ATPase activity by DnaJ, nucleotide exchange is still efficiently stimulated by GrpE. This indicates that two counteracting factors are not absolutely necessary to maintain a functional and regulated chaperone cycle. This conclusion is corroborated by data that show that the slower ATPase cycle of the DnaK system as well as of heterologous T. thermophilus DnaK/E. coli DnaK systems is directly reflected in altered refolding kinetics of firefly luciferase but not necessarily in refolding yields.     

D-Peptides as inhibitors of the DnaK/DnaJ/GrpE chaperone system

DnaK, a Hsp70 homolog of Escherichia coli, together with its co-chaperones DnaJ and GrpE protects denatured proteins from aggregation and promotes their refolding by an ATP-consuming mechanism. DnaJ not only stimulates the gamma-phosphate cleavage of DnaK-bound ATP but also binds polypeptide substrates on its own. Unfolded polypeptides, such as denatured luciferase, thus form ternary complexes with DnaJ and DnaK. A previous study has shown that d-peptides compete with l-peptides for the same binding site in DnaJ but do not bind to DnaK (Feifel, B., Sch?nfeld, H.-J., and Christen, P. (1998) J. Biol. Chem. 273, 11999-12002). Here we report that d-peptides efficiently inhibit the refolding of denatured luciferase by the DnaK/DnaJ/GrpE chaperone system (EC50 = 1-2 microM). The inhibition of the chaperone action is due to the binding of d-peptide to DnaJ (Kd = 1-2 microM), which seems to preclude DnaJ from forming ternary (ATP.DnaK)m.substrate.DnaJn complexes. Apparently, simultaneous binding of DnaJ and DnaK to one and the same target polypeptide is essential for effective chaperone action.     

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.     

Dicarboxylic amino acids and glycine-betaine regulate chaperone-mediated protein-disaggregation under stress

Active protein-disaggregation by a chaperone network composed of ClpB and DnaK + DnaJ + GrpE is essential for the recovery of stress-induced protein aggregates in vitro and in Escherichia coli cells. K-glutamate and glycine-betaine (betaine) naturally accumulate in salt-stressed cells. In addition to providing thermo-protection to native proteins, we found that these osmolytes can strongly and specifically activate ClpB, resulting in an increased efficiency of chaperone-mediated protein disaggregation. Moreover, factors that inhibited the chaperone network by impairing the stability of the ClpB oligomer, such as natural polyamines, dilution, or high salt, were efficiently counteracted by K-glutamate or betaine. The combined protective, counter-negative and net activatory effects of K-glutamate and betaine, allowed protein disaggregation and refolding under heat-shock temperatures that otherwise cause protein aggregation in vitro and in the cell. Mesophilic organisms may thus benefit from a thermotolerant osmolyte-activated chaperone mechanism that can actively rescue protein aggregates, correctly refold and maintain them in a native state under heat-shock conditions.     

The importance of having thermosensor control in the DnaK chaperone system

In addition to the sigma(32)-mediated heat shock response, the DnaK/DnaJ/GrpE molecular chaperone system of Escherichia coli directly adapts to elevated temperatures by sequestering a higher fraction of substrate. This immediate heat shock response is due to the differential temperature dependence of the activity of DnaJ, which stimulates the hydrolysis of DnaK-bound ATP, and the activity of GrpE, which facilitates ADP/ATP exchange and converts DnaK from its high-affinity ADP-liganded state into its low-affinity ATP-liganded state. GrpE acts as thermosensor with its ADP/ATP exchange activity decreasing above 40 degrees C. To assess the importance of this reversible thermal adaptation for the chaperone action of the DnaK/DnaJ/GrpE system during heat shock, we used glucose-6-phosphate dehydrogenase and luciferase as substrates. We compared the performance of wild-type GrpE as a component of the chaperone system with that of GrpE R40C. In this mutant, the thermosensing helices are stabilized with an intersubunit disulfide bond and its nucleotide exchange activity thus increases continuously with increasing temperature. Wild-type GrpE with intact thermosensor proved superior to GrpE R40C with desensitized thermosensor. The chaperone system with wild-type GrpE yielded not only a higher fraction of refolding-competent protein at the end of a heat shock but also protected luciferase more efficiently against inactivation during heat shock. Consistent with their differential thermal behavior, the protective effects of wild-type GrpE and GrpE R40C diverged more and more with increasing temperature. Thus, the direct thermal adaptation of the DnaK chaperone system by thermosensing GrpE is essential for efficient chaperone action during heat shock.     

Thermosensor action of GrpE. The DnaK chaperone system at heat shock temperatures

Temperature directly controls functional properties of the DnaK/DnaJ/GrpE chaperone system. The rate of the high to low affinity conversion of DnaK shows a non-Arrhenius temperature dependence and above approximately 40 degrees C even decreases. In the same temperature range, the ADP/ATP exchange factor GrpE undergoes an extensive, fully reversible thermal transition (Grimshaw, J. P. A., Jelesarov, I., Sch?nfeld, H. J., and Christen, P. (2001) J. Biol. Chem. 276, 6098-6104). To show that this transition underlies the thermal regulation of the chaperone system, we introduced an intersubunit disulfide bond into the paired long helices of the GrpE dimer. The transition was absent in disulfide-linked GrpE R40C but was restored by reduction. With disulfide-stabilized GrpE, the rate of ADP/ATP exchange and conversion of DnaK from its ADP-liganded high affinity R state to the ATP-liganded low affinity T state continuously increased with increasing temperature. With reduced GrpE R40C, the conversion became slower at temperatures >40 degrees C, as observed with wild-type GrpE. Thus, the long helix pair in the GrpE dimer acts as a thermosensor that, by decreasing its ADP/ATP exchange activity, induces a shift of the DnaK.substrate complexes toward the high affinity R state and in this way adapts the DnaK/DnaJ/GrpE system to heat shock conditions.     

Balance of ATPase stimulation and nucleotide exchange is not required for efficient refolding activity of the DnaK chaperone

The DnaK system from Thermus thermophilus (DnaK(Tth)) exhibits pronounced differences in organisation and regulation to its mesophile counterpart from Escherichia coli (DnaK(Eco)). While the ATPase cycle of DnaK(Eco) is tightly regulated by the concerted action of the two cofactors DnaJ(Eco) and GrpE(Eco), the DnaK(Tth) system features an imbalance in this cochaperone mediated regulation. GrpE(Tth) considerably accelerates the ATP/ADP exchange, but DnaJ(Tth) only slightly stimulates ATPase activity, believed to be a key step for chaperone activity of DnaK(Eco). By in vitro complementation assays, we could not detect significant ATPase-stimulation of orthologous DnaJ(Tth) . DnaKEco or DnaJ(Eco). DnaK(Tth)-complexes as compared to the DnaK(Eco) system, although they were nevertheless active in luciferase refolding experiments. Assistance of protein recovery by DnaK thus seems to be uncoupled of the magnitude of DnaJ mediated ATPase-stimulation.     

DnaK, DnaJ and GrpE form a cellular chaperone machinery capable of repairing heat-induced protein damage.

Members of the conserved Hsp70 chaperone family are assumed to constitute a main cellular system for the prevention and the amelioration of stress-induced protein damage, though little direct evidence exists for this function. We investigated the roles of the DnaK (Hsp70), DnaJ and GrpE chaperones of Escherichia coli in prevention and repair of thermally induced protein damage using firefly luciferase as a test substrate. In vivo, luciferase was rapidly inactivated at 42 degrees C, but was efficiently reactivated to 50% of its initial activity during subsequent incubation at 30 degrees C. DnaK, DnaJ and GrpE did not prevent luciferase inactivation, but were essential for its reactivation. In vitro, reactivation of heat-inactivated luciferase to 80% of its initial activity required the combined activity of DnaK, DnaJ and GrpE as well as ATP, but not GroEL and GroES. DnaJ associated with denatured luciferase, targeted DnaK to the substrate and co-operated with DnaK to prevent luciferase aggregation at 42 degrees C, an activity that was required for subsequent reactivation. The protein repair function of DnaK, GrpE and, in particular, DnaJ is likely to be part of the role of these proteins in regulation of the heat shock response.     

CbpA, a DnaJ homolog, is a DnaK co-chaperone, and its activity is modulated by CbpM

The DnaK chaperone system, consisting of DnaK, DnaJ, and GrpE, remodels and refolds proteins during both normal growth and stress conditions. CbpA, one of several DnaJ analogs in Escherichia coli, is known to function as a multicopy suppressor for dnaJ mutations and to bind nonspecifically to DNA and preferentially to curved DNA. We found that CbpA functions as a DnaJ-like co-chaperone in vitro. CbpA acted in an ATP-dependent reaction with DnaK and GrpE to remodel inactive dimers of plasmid P1 RepA into monomers active in P1 DNA binding. Additionally, CbpA participated with DnaK in an ATP-dependent reaction to prevent aggregation of denatured rhodanese. The cbpA gene is in an operon with an open reading frame, yccD, which encodes a protein that has some homology to DafA of Thermus thermophilus. DafA is a protein required for the assembly of ring-like particles that contain trimers each of T. thermophilus DnaK, DnaJ, and DafA. The E. coli YccD was isolated because of its potential functional relationship to CbpA. Purified YccD specifically inhibited both the co-chaperone activity and the DNA binding activity of CbpA, suggesting that YccD modulates the activity of CbpA. We named the product of the yccD gene CbpM for "CbpA modulator."     

Relaxation of replication control in chaperone-independent initiator mutants of plasmid P1.

Escherichia coli chaperones DnaJ, DnaK and GrpE increase P1 plasmid initiator binding to the origin by promoting initiator folding. The binding allows initiation and also promotes pairing of origins which is believed to control initiation frequency. Chaperone-independent DNA binding mutants are often defective in replication control. We show here that these mutants have increased rates of association for DNA binding and defects in origin pairing. The increases in association rates were found to be due either to increased protein folding into active forms or to increases in the association rate constant, kon. Since the dissociation rate constants for DNA release with these mutants are not changed, it is unlikely that the DNA binding domain is affected. The pairing domain may thus control replication and modulate DNA binding. The role of the pairing domain in DNA binding can be significant in vivo as the selection for chaperone-independent binding favors pairing-defective mutants.     

The roles of the two zinc binding sites in DnaJ

All type I DnaJ (Hsp40) homologues share the presence of two highly conserved zinc centers. To elucidate their function, we constructed DnaJ mutants that separately replaced cysteines of either zinc center I or zinc center II with serine residues. We found that in the absence of zinc center I, the autonomous, DnaK-independent chaperone activity of DnaJ is dramatically reduced. Surprisingly, this only slightly impaired the in vivo function of DnaJ, and its ability to function as a co-chaperone in the DnaK/DnaJ/GrpE foldase machine. The DnaJ zinc center II, on the other hand, was found to be absolutely essential for the in vivo and in vitro function of DnaJ. This did not seem to be caused by a lack of substrate binding affinity or an inability to work as an ATPase-stimulating factor. Rather it appears that zinc center II mutant proteins lack a necessary additional interaction site with DnaK, which seems to be crucial for locking-in substrate proteins onto DnaK. These findings led us to a model in which ATP hydrolysis in DnaK is only the first step in converting DnaK into its high affinity binding state. Additional interactions between DnaK and DnaJ are required to make the DnaK/DnaJ/GrpE foldase machinery catalytically active.     

Functional similarities and differences of an archaeal Hsp70(DnaK) stress protein compared with its homologue from the bacterium Escherichia coli

Archaea are prokaryotes but some of their chaperoning systems resemble those of eukaryotes. Also, not all archaea possess the stress protein Hsp70(DnaK), in contrast with bacteria and eukaryotes, which possess it without any known exception. Further, the primary structure of the archaeal DnaK resembles more the bacterial than the eukaryotic homologues. The work reported here addresses two questions: Is the archaeal Hsp70 protein a chaperone, like its homologues in the other two phylogenetic domains? And, if so, is the chaperoning mechanism of bacterial or eukaryotic type? The data have shown that the DnaK protein of the archaeon Methanosarcina mazei functions efficiently as a chaperone in luciferase renaturation in vitro, and that it requires DnaJ, and the other bacterial-type chaperone, GrpE, to perform its function. The M. mazei DnaK chaperone activity was enhanced by interaction with the bacterial co-chaperone DnaJ, but not by the eukaryotic homologue HDJ-2. Both the bacterial GrpE and DnaJ stimulated the ATPase activity of the M. mazei DnaK. The M. mazei DnaK-dependent chaperoning pathway in vitro is similar to that of the bacterium Escherichia coli used for comparison. However, in vivo analyses indicate that there are also significant differences. The M. mazei dnaJ and grpE genes rescued E.coli mutants lacking these genes, but E.coli dnaK mutants were not complemented by the M. mazei dnaK gene. Thus, while the data from in vitro tests demonstrate functional similarities between the M. mazei and E.coli DnaK proteins, in vivo results indicate that, intracellularly, the chaperones from the two species differ.     

Biochemical characterization of the apicoplast-targeted AAA+ ATPase ClpB from Plasmodium falciparum

ClpB is a molecular chaperone from the AAA+ superfamily of ATPases, which reactivates aggregated proteins in cooperation with the DnaK chaperone system. ClpB is essential for infectivity and in-host survival of a number of pathogenic microorganisms, but systematic studies on ClpB from pathogens have not been reported yet. We purified and characterized one of the two ClpB isoforms from the malaria parasite Plasmodium falciparum, PfClpB1. PfClpB1 is targeted to the apicoplast, an essential plastid organelle that is a promising anti-malaria drug target. PfClpB1 contains all characteristic AAA+ sequence motifs, but the middle domain of PfClpB1 includes a 52-residue long non-conserved insert. Like in most AAA+ ATPases, ATP induces self-association of PfClpB1 into hexamers. PfClpB1 catalyzes the hydrolysis of ATP and its ATPase activity is activated in the presence of casein and poly-lysine. Similar to Escherichia coli ClpB, PfClpB1 reactivates aggregated firefly luciferase, but the PfClpB1-mediated aggregate reactivation is inhibited in the presence of E. coli DnaK, DnaJ, and GrpE. The lack of effective cooperation between PfClpB1 and the bacterial DnaK system may arise from the Plasmodium-specific sequence of the ClpB middle domain. Our results indicate that the chaperone activity of PfClpB1 may support survival of Plasmodium falciparum by maintaining the folding status and activity of apicoplast proteins.