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

Analysis of the AAA sensor-2 motif in the C-terminal ATPase domain of Hsp104 with a site-specific fluorescent probe of nucleotide binding

Hsp104 from Saccharomyces cerevisiae is a hexameric protein with two AAA ATPase domains (N- and C-terminal nucleotide-binding domains NBD1 and NBD2, respectively) per monomer. Our previous analysis of the Hsp104 ATP hydrolysis cycle revealed that NBD1 and NBD2 have very different catalytic properties, but each shows positive cooperativity in hydrolysis. There is also communication between the two domains, in that ATP hydrolysis at NBD1 depends on the nucleotide that is bound to NBD2. Here, we extend our understanding of the Hsp104 ATP hydrolysis cycle through mutagenesis of the AAA sensor-2 motif in NBD2. To do so, we took advantage of the lack of tryptophan residues in Hsp104 to place a single tryptophan in the C-terminal domain (Y819W). The Y819W substitution has no significant effects on folding stability of the C-terminal domain or on ATP hydrolysis by NBD1 or NBD2. The fluorescence of this tryptophan changes in response to ATP and ADP binding, allowing the K(d) and Hill coefficient to be determined for each nucleotide. By using this site-specific probe of binding, we analyze the effect of mutating the conserved arginine residue in the sensor-2 motif in Hsp104 NBD2. An R826M mutation causes nearly equal decreases in affinity of NBD2 for both ATP and ADP, indicating that at this site, the sensor-2 provides binding energy, but does not act to sense the difference between these nucleotides. In addition, the rate of ATP hydrolysis at NBD1 is decreased by the R826M mutation, providing further evidence for interdomain communication in the Hsp104 ATP hydrolysis cycle.

Roles of the two ATP binding sites of ClpB from Thermus thermophilus

As a member of molecular chaperone Hsp100/Clp family, TClpB from Thermus thermophilus has two nucleotide binding domains, NBD1 and NBD2, in a single polypeptide, each containing WalkerA and WalkerB consensus motifs. To probe their roles, mutations were introduced into the WalkerA or WalkerB motifs of each or both of the NBDs. The results are as follows. 1) For each of the NBDs, the ability of nucleotide binding is lost by mutations in the WalkerA motif but is retained by mutations in the WalkerB motif. 2) Each NBD has a casein-stimulatable small basic ATPase activity that is lost when the WalkerB motif is mutated. 3) TClpB assembles into a uniform 580-kDa oligomer when ATP is present at 55 degrees C, and only the mutants in the WalkerA motif in NBD1 fail to assemble, indicating that ATP binding to NBD1 but not hydrolysis is necessary and sufficient for the assembly. 4) Chaperone function of TClpB was lost when the WalkerA motif in each of the NBDs was mutated. Mutants in the WalkerB motifs of each NBD retained some chaperone activity.

Cooperative kinetics of both Hsp104 ATPase domains and interdomain communication revealed by AAA sensor-1 mutants

AAA proteins share a conserved active site for ATP hydrolysis and regulate many cellular processes. AAA proteins are oligomeric and often have multiple ATPase domains per monomer, which is suggestive of complex allosteric kinetics of ATP hydrolysis. Here, using wild-type Hsp104 in the hexameric state, we demonstrate that its two AAA modules (NBD1 and NBD2) have very different catalytic activities, but each displays cooperative kinetics of hydrolysis. Using mutations in the AAA sensor-1 motif of NBD1 and NBD2 that reduce the rate of ATP hydrolysis without affecting nucleotide binding, we also examine the consequences of keeping each site in the ATP-bound state. In vitro, reducing k(cat) at NBD2 significantly alters the steady-state kinetic behavior of NBD1. Thus, Hsp104 exhibits allosteric communication between the two sites in addition to homotypic cooperativity at both NBD1 and NBD2. In vivo, each sensor-1 mutation causes a loss-of-function phenotype in two assays of Hsp104 function (thermotolerance and yeast prion propagation), demonstrating the importance of ATP hydrolysis as distinct from ATP binding at each site for Hsp104 function.

[PSI+], SUP35, and chaperones

Biochemical characterization of the yeast prions has revealed many similarities with the mammalian amyloidogenic proteins. The ease of generating in vivo mutations in yeast and the developing in vitro models for [PSI+] and [URE3] circumvent many of the difficulties of studying the proteins linked to the mammalian amyloidoses. Future work especially aimed at understanding the molecular role of chaperone proteins in regulating conversion as well as the early steps in de novo formation of the prion state in yeast will likely provide invaluable lessons that may be more broadly applicable to related processes in higher eukaryotes. It is important to remember, however, that there are clear distinctions between disease states associated with amyloidogenesis and the epigenetic modulation of protein function by self-perpetuating conformational conversions. Amyloid formation is detrimental to mammals and is likely selected against, providing a possible explanation for the late onset of these disorders (Lansbury, 1999). In contrast, the known yeast prions are compatible with normal growth and, if beneficial to the organism, may be subject to evolutionary pressures that ultimately maximize transmission. In the prion proteins examined to date, distinct domains are responsible for normal function and for the conformational switches producing a prion conversion of that function. Recent work has demonstrated that the prion domains are both modular and transferable to other proteins on which they can confer a heritable epigenetic alteration of function (Edskes et al., 1999; Li and Lindquist, 2000; Patino et al., 1996; Santoso et al., 2000; Sondheimer and Lindquist, 2000). That is, prion domains need not coevolve with particular functional domains but might be moved from one protein to another during evolution. Such processes may be widely used in biology. Mechanistic studies of [PSI+] and [URE3] replication are sure to lay a foundation of knowledge for understanding a host of nonconventional genetic elements that currently remain elusive.

Catalytic activity and chaperone function of human protein-disulfide isomerase are required for the efficient refolding of proinsulin

Protein-disulfide isomerase (PDI) catalyzes the formation, rearrangement, and breakage of disulfide bonds and is capable of binding peptides and unfolded proteins in a chaperone-like manner. In this study we examined which of these functions are required to facilitate efficient refolding of denatured and reduced proinsulin. In our model system, PDI and also a PDI mutant having only one active site increased the rate of oxidative folding when present in catalytic amounts. PDI variants that are completely devoid of isomerase activity are not able to accelerate proinsulin folding, but can increase the yield of refolding, indicating that they act as a chaperone. Maximum refolding yields, however, are only achieved with wild-type PDI. Using genistein, an inhibitor for the peptide-binding site, the ability of PDI to prevent aggregation of folding proinsulin was significantly suppressed. The present results suggest that PDI is acting both as an isomerase and as a chaperone during folding and disulfide bond formation of proinsulin.

Importance of two ATP-binding sites for oligomerization, ATPase activity and chaperone function of mitochondrial Hsp78 protein

The yeast mitochondrial chaperone Hsp78, a homologue of yeast cytosolic Hsp104 and bacterial ClpB, is required for maintenance of mitochondrial functions under heat stress. Here, Hsp78 was purified to homogeneity and shown to form a homo-hexameric complex, with an apparent molecular mass of approximately 440 kDa, in an ATP-dependent manner. Analysis of its ATPase activity reveals that the observed positive cooperativity effect depends both on Hsp78 and ATP concentration. Site-directed mutagenesis of the two putative Hsp78 nucleotide-binding domains suggest that the first nucleotide-binding domain is responsible for ATP hydrolysis and the second one for protein oligomerization. Studies on the chaperone activity of Hsp78 show that its cooperation with the mitochondrial Hsp70 system, consisting of Ssc1p, Mdj1p and Mge1p, is needed for the efficient reactivation of substrate proteins. These studies also suggest that the oligomerization but not the Hsp78 ATPase activity is essential for its chaperone activity.

The effect of co-overproduction of DnaK/DnaJ/GrpE and ClpB proteins on the removal of heat-aggregated proteins from Escherichia coli DeltaclpB mutant cells--new insight into the role of Hsp70 in a functional cooperation with Hsp100

The effect of overproduction of the Hsp70 system proteins (DnaK, DnaJ, GrpE) and/or ClpB (Hsp100) from plasmids on the process of formation and removal of heat-aggregated proteins from Escherichia coli cells (the S fraction) was investigated by sucrose density gradient centrifugation. Two plasmids were employed: pKJE7 carrying the dnaK/dnaJ/grpE genes under the control of the araB promoter and pClpB carrying the clpB gene under the control of its own promoter (sigma(32)-dependent). In the wild-type cells the S fraction after 15 min of heat shock amounted to 21% of cellular insoluble proteins (IP), and disappeared 10 min after transfer of the culture to 37 degrees C. In contrast to this, in the clpB mutant the S fraction was larger (35% IP) and its elimination was retarded, nearly 60% of the aggregated proteins remained stable 30 min after heat shock. This result points to the importance of ClpB in removal of the heat-aggregated proteins from cells. Overproduction of the Hsp70 system proteins (exceeding by about 1.5-fold that of wild-type) in wild-type and DeltaclpB cells completely prevented the formation of the S fraction during heat shock. Overproduction of ClpB (exceeding by about eight-fold that of wild-type) in the same background did not prevent protein aggregation after heat shock and only partly compensated for the effect of the mutation in the clpB gene. Monitoring the S fraction during co-production of DnaK/DnaJ/GrpE and ClpB in the DeltaclpB mutant revealed that both the levels of expression and the ratios of ClpB to Hsp70 system proteins had a significant effect on the formation and removal of protein aggregates in heat-shocked E. coli cells. In the presence of excess ClpB, an increase in the levels of DnaK, DnaJ and GrpE was required to prevent aggregate formation upon heat shock or to efficiently remove protein aggregates after heat shock. Therefore, it is supposed that a high level of ClpB under some conditions, especially at insufficient levels of Hsp70 system proteins, may support protein aggregation resulting from heat shock and may lead to stabilization of hydrophobic aggregates.

Microbial molecular chaperones

Protein folding in the cell, long thought to be a spontaneous process, in fact often requires the assistance of molecular chaperones. This is thought to be largely because of the danger of incorrect folding and aggregation of proteins, which is a particular problem in the crowded environment of the cell. Molecular chaperones are involved in numerous processes in bacterial cells, including assisting the folding of newly synthesized proteins, both during and after translation; assisting in protein secretion, preventing aggregation of proteins on heat shock, and repairing proteins that have been damaged or misfolded by stresses such as a heat shock. Within the cell, a balance has to be found between refolding of proteins and their proteolytic degradation, and molecular chaperones play a key role in this. In this review, the evidence for the existence and role of the major cytoplasmic molecular chaperones will be discussed, mainly from the physiological point of view but also in relationship to their known structure, function and mechanism of action. The two major chaperone systems in bacterial cells (as typified by Escherichia coli) are the GroE and DnaK chaperones, and the contrasting roles and mechanisms of these chaperones will be presented. The GroE chaperone machine acts by providing a protected environment in which protein folding of individual protein molecules can proceed, whereas the DnaK chaperones act by binding and protecting exposed regions on unfolded or partially folded protein chains. DnaK chaperones interact with trigger factor in protein translation and with ClpB in reactivating proteins which have become aggregated after heat shock. The nature of the other cytoplasmic chaperones in the cell will also be reviewed, including those for which a clear function has not yet been determined, and those where an in vivo chaperone function has still to be proven, such as the small heat shock proteins IbpA and IbpB. The regulation of expression of the genes of the heat shock response will also be discussed, particularly in the light of the signals that are needed to induce the response. The major signals for induction of the heat shock response are elevated temperature and the presence of unfolded protein within the cell, but these are sensed and transduced differently by different bacteria. The best characterized example is the sigma 32 subunit of RNA polymerase from E. coli, which is both more efficiently translated and also transiently stabilized following heat shock. The DnaK chaperones modulate this effect. However, a more widely conserved system appears to be typified by the HrcA repressor in Bacillus subtilis, the activity of which is modulated by the GroE chaperone machine. Other examples of regulation of molecular chaperones will also be discussed. Finally, the likely future research directions for molecular chaperone biology in the post-genomic era will be briefly evaluated.

DnaK/DnaJ chaperone system reactivates endogenous E. coli thermostable FBP aldolase in vivo and in vitro; the effect is enhanced by GroE heat shock proteins

Thermally aggregated, endogenous proteins in Escherichia coli cells form the S fraction, which is separable by sucrose density gradient centrifugation. To date, relatively little is known about the mechanisms of elimination of the heat-aggregated proteins from E. coli cells and the composition of the S fraction. We have identified several proteins of the S fraction using 2D-gel electrophoresis and microsequencing. A thermostable II class fructose-1,6-bisphosphate aldolase (Fda protein) appeared to be one of numerous proteins of the S fraction. Fda was purified from E. coli overproducer strain and used as a model substrate for investigation of the role of Hsps in prevention and repair of thermal denaturation of proteins both in vivo and in vitro. We found that the heat inactivation of Fda was reversible and that its reactivation in vivo and in vitro required mainly the assistance of the DnaK/DnaJ chaperone system. The dnaK756 and dnaJ259 mutations had a negative effect on the reactivation of thermally inactivated Fda. Moreover, we showed that the reactivation process in vitro was enhanced when GroEL/GroES were added together with DnaK/DnaJ. GroEL/GroES alone were inefficient in the resolubilization or reactivation of the heat-aggregated Fda. It is supposed that the denaturation of the thermostable Fda in vivo results rather from a temporary and transient deficit of Hsps than from the direct heat effect.

Review: mechanisms of disaggregation and refolding of stable protein aggregates by molecular chaperones

Molecular chaperones are essential for the correct folding of proteins in the cell under physiological and stress conditions. Two activities have been traditionally attributed to molecular chaperones: (1) preventing aggregation of unfolded polypeptides and (2) assisting in the correct refolding of chaperone-bound denatured polypeptides. We discuss here a novel function of molecular chaperones: catalytic solubilization and refolding of stable protein aggregates. In Escherichia coli, disaggregation is carried out by a network of ATPase chaperones consisting of a DnaK core, assisted by the cochaperones DnaJ, GrpE, ClpB, and GroEL-GroES. We suggest a sequential mechanism in which (a) ClpB exposes new DnaK-binding sites on the surface of the stable protein aggregates; (b) DnaK binds the aggregate surfaces and, by doing so, melts the incorrect hydrophobic associations between aggregated polypeptides; (c) ATP hydrolysis and DnaK release allow local intramolecular refolding of native domains, leading to a gradual weakening of improper intermolecular links; (d) DnaK and GroEL complete refolding of solubilized polypeptide chains into native proteins. Thus, active disaggregation by the chaperone network can serve as a central cellular tool for the recovery of native proteins from stress-induced aggregates and actively remove disease-causing toxic aggregates, such as polyglutamine-rich proteins, amyloid plaques, and prions.

Hsp101 is necessary for heat tolerance but dispensable for development and germination in the absence of stress

Hsp101 is a molecular chaperone that is required for the development of thermotolerance in plants and other organisms. We report that Arabidopsis thaliana Hsp101 is also regulated during seed development in the absence of stress, in a pattern similar to that seen for LEA proteins and small Hsps; protein accumulates during mid-maturation and is stored in the dry seed. Two new alleles of the locus encoding Hsp101 (HOT1) were isolated from Arabidopsis T-DNA mutant populations. One allele, hot1-3, contains an insertion within the second exon and is null for Hsp101 protein expression. Despite the complete absence of Hsp101 protein, plant growth and development, as well as seed germination, are normal, demonstrating that Hsp101 chaperone activity is not essential in the absence of stress. In thermotolerance assays hot1-3 shows a similar, though somewhat more severe, phenotype to the previously described missense allele hot1-1, revealing that the hot1-1 mutation is also close to null for protein activity. The second new mutant allele, hot1-2, has an insertion in the promoter 101 bp 5' to the putative TATA element. During heat stress the hot1-2 mutant produces normal levels of protein in hypocotyls and 10-day-old seedlings, and it is wild type for thermotolerance at these stages. Thus this mutation has not disrupted the minimal promoter sequence required for heat regulation of Hsp101. The hot1-2 mutant also expresses Hsp101 in seeds, but at a tenfold reduced level, resulting in reduced thermotolerance of germinating seeds and underscoring the importance of Hsp101 to seed stress tolerance.

In vivo proteolytic degradation of the Escherichia coli acyltransferase HlyC

Escherichia coli hemolysin (HlyA) is the prototype toxin of a major family of exoproteins produced by Gram-negative bacteria known as "repeats in toxins." Only fatty acid-acylated HlyA molecules at residues Lys564 and Lys690 are able to damage the target cell membrane. Fatty acylation of pro-HlyA is dependent on the co-synthesized acyltransferase HlyC and the acylated form of acyl-carrier protein. By using a collection of hlyA and hlyC mutant strains, the processing of HlyC was investigated. HlyC was not detected by Western blot in an E. coli strain encoding hlyC and hlyA, but it was present in a strain encoding only hlyC. The hlyC mRNA pattern, however, was similar in both strains indicating that the turnover of HlyC does not occur at the transcriptional level. HlyC was detected in Western blots of cell lysates from an E. coli strain encoding HlyC and a HlyA derivative where both acylation sites were substituted. Similar results were obtained when HlyC was expressed in a hlyA mutant strain lacking part of a putative HlyC binding domain, indicating that this particular HlyA region affects HlyC stability. We did not detect HlyC in cell lysates from hlyC mutants with different abilities to acylate pro-HlyA, suggesting that the degradation of HlyC is not related to the HlyA acylation process. The protease systems ClpAP, ClpXP, and FtsH were found to be responsible for the HlyA-dependent processing of HlyC.

Characterization of Brucella suis clpB and clpAB mutants and participation of the genes in stress responses

Pathogens often encounter stressful conditions inside their hosts. In the attempt to characterize the stress response in Brucella suis, a gene highly homologous to Escherichia coli clpB was isolated from Brucella suis, and the deduced amino acid sequence showed features typical of the ClpB ATPase family of stress response proteins. Under high-temperature stress conditions, ClpB of B. suis was induced, and an isogenic B. suis clpB mutant showed increased sensitivity to high temperature, but also to ethanol stress and acid pH. The effects were reversible by complementation. Simultaneous inactivation of clpA and clpB resulted in a mutant that was sensitive to oxidative stress. In B. suis expressing gfp, ClpA but not ClpB participated in degradation of the green fluorescent protein at 42 degrees C. We concluded that ClpB was responsible for tolerance to several stresses and that the lethality caused by harsh environmental conditions may have similar molecular origins.

The chaperone function of ClpB from Thermus thermophilus depends on allosteric interactions of its two ATP-binding sites

ClpB belongs to the Hsp100 family and assists de-aggregation of protein aggregates by DnaK chaperone systems. It contains two Walker consensus sequences (or P-Loops) that indicate potential nucleotide binding domains (NBD). Both domains appear to be essential for chaperoning function, since mutation of the conserved lysine residue of the GX(4)GKT consensus sequences to glutamine (K204Q and K601Q) abolishes its properties to accelerate renaturation of aggregated firefly luciferase. The underlying biochemical reason for this malfunction appears not to be a dramatically reduced ATPase activity of either P-loop per se but rather changed properties of co-operativity of ATPase activity connected to oligomerization properties to form productive oligomers. This view is corroborated by data that show that structural stability (as judged by CD spectroscopy) or ATPase activity at single turnover conditions (at low ATP concentrations) are not significantly affected by these mutations. In addition nucleotide binding properties of wild-type protein and mutants (as judged by binding studies with fluorescent nucleotide analogues and competitive displacement titrations) do not differ dramatically. However, the general pattern of formation of stable, defined oligomers formed as a function of salt concentration and nucleotides and more importantly, cooperativity of ATPase activity at high ATP concentrations is dramatically changed with the two P-loop mutants described.

Interim report on genomics of Escherichia coli

We present a summary of recent progress in understanding Escherichia coli K-12 gene and protein functions. New information has come both from classical biological experimentation and from using the analytical tools of functional genomics. The content of the E. coli genome can clearly be seen to contain elements acquired by horizontal transfer. Nevertheless, there is probably a large, stable core of >3500 genes that are shared among all E. coli strains. The gene-enzyme relationship is examined, and, in many cases, it exhibits complexity beyond a simple one-to-one relationship. Also, the E. coli genome can now be seen to contain many multiple enzymes that carry out the same or closely similar reactions. Some are similar in sequence and may share common ancestry; some are not. We discuss the concept of a minimal genome as being variable among organisms and obligatorily linked to their life styles and defined environmental conditions. We also address classification of functions of gene products and avenues of insight into the history of protein evolution.

Kinetic model of in vivo folding and inclusion body formation in recombinant Escherichia coli

Aggregation of misfolded proteins can reduce the yield in recombinant protein production. The underlying complex processes are additionally influenced by cellular physiology. Nevertheless, a lumped-parameter model of kinetic competition between folding and aggregation was sufficient to track properly the specific concentration of a human protein produced in E. coli and its partitioning into soluble and insoluble cell fractions. Accurate estimation of the protein-specific parameters required informative experiments, which were designed using the Fisher information matrix. The model was employed to calculate the influence of the specific glucose uptake rate in high-cell-density cultivation of E. coli on accumulation and aggregation of the recombinant protein. Despite its simplicity, the model was flexible and unbiased concerning unidentified mechanisms. Assuming an exponentially decreasing production rate, the irreversible aggregation step was found to follow first order kinetics, while assuming a constant production rate with simultaneous degradation, the model predicted transient aggregation only. Implications for strain and process development are discussed.

Mitochondrial Hsp78, a member of the Clp/Hsp100 family in Saccharomyces cerevisiae, cooperates with Hsp70 in protein refolding

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.

DnaK/DnaJ chaperone system reactivates endogenous E. coli thermostable FBP aldolase in vivo and in vitro; the effect is enhanced by GroE heat shock proteins

Thermally aggregated, endogenous proteins in Escherichia coli cells form the S fraction, which is separable by sucrose density gradient centrifugation. To date, relatively little is known about the mechanisms of elimination of the heat-aggregated proteins from E. coli cells and the composition of the S fraction. We have identified several proteins of the S fraction using 2D-gel electrophoresis and microsequencing. A thermostable II class fructose-1,6-bisphosphate aldolase (Fda protein) appeared to be one of numerous proteins of the S fraction. Fda was purified from E. coli overproducer strain and used as a model substrate for investigation of the role of Hsps in prevention and repair of thermal denaturation of proteins both in vivo and in vitro. We found that the heat inactivation of Fda was reversible and that its reactivation in vivo and in vitro required mainly the assistance of the DnaK/DnaJ chaperone system. The dnaK756 and dnaJ259 mutations had a negative effect on the reactivation of thermally inactivated Fda. Moreover, we showed that the reactivation process in vitro was enhanced when GroEL/GroES were added together with DnaK/DnaJ. GroEL/GroES alone were inefficient in the resolubilization or reactivation of the heat-aggregated Fda. It is supposed that the denaturation of the thermostable Fda in vivo results rather from a temporary and transient deficit of Hsps than from the direct heat effect.

Structure and activity of ClpB from Escherichia coli. Role of the amino-and -carboxyl-terminal domains

ClpB is a member of a protein-disaggregating multi-chaperone system in Escherichia coli. The mechanism of protein-folding reactions mediated by ClpB is currently unknown, and the functional role of different sequence regions in ClpB is under discussion. We have expressed and purified the full-length ClpB and three truncated variants with the N-terminal, C-terminal, and a double N- and C-terminal deletion. We studied the protein concentration-dependent and ATP-induced oligomerization of ClpB, casein-induced activation of ClpB ATPase, and ClpB-assisted reactivation of denatured firefly luciferase. We found that both the N- and C-terminal truncation of ClpB strongly inhibited its chaperone activity. The reasons for such inhibition were different, however, for the N- and C-terminal truncation. Deletion of the C-terminal domain inhibited the self-association of ClpB, which led to decreased affinity for ATP and to decreased ATPase and chaperone activity of the C-terminally truncated variants. In contrast, deletion of the N-terminal domain did not inhibit the self-association of ClpB and its basal ATPase activity but decreased the ability of casein to activate ClpB ATPase. These results indicate that the N-terminal region of ClpB may contain a functionally significant protein-binding site, whereas the main role of the C-terminal region is to support oligomerization of ClpB.

The truncated form of the bacterial heat shock protein ClpB/HSP100 contributes to development of thermotolerance in the cyanobacterium Synechococcus sp. strain PCC 7942

ClpB is a highly conserved heat shock protein that is essential for thermotolerance in bacteria and eukaryotes. One distinctive feature of all bacterial clpB genes is the dual translation of a truncated 79-kDa form (ClpB-79) in addition to the full-length 93-kDa protein (ClpB-93). To investigate the currently unknown function of ClpB-79, we have examined the ability of the two different-sized ClpB homologues from the cyanobacterium Synechococcus sp. strain PCC 7942 to confer thermotolerance. We show that the ClpB-79 form has the same capacity as ClpB-93 to confer thermotolerance and that the ClpB-79 protein contributes ca. one-third of the total thermotolerance developed in wild-type Synechococcus, the first in vivo demonstration of a functional role for ClpB-79 in bacteria.

Substrate recognition by the ClpA chaperone component of ClpAP protease

ClpA, a member of the Clp/Hsp100 ATPase family, is a molecular chaperone and regulatory component of ClpAP protease. We explored the mechanism of protein recognition by ClpA using a high affinity substrate, RepA, which is activated for DNA binding by ClpA and degraded by ClpAP. By characterizing RepA derivatives with N- or C-terminal deletions, we found that the N-terminal portion of RepA is required for recognition. More precisely, RepA derivatives lacking the N-terminal 5 or 10 amino acids are degraded by ClpAP at a rate similar to full-length RepA, whereas RepA derivatives lacking 15 or 20 amino acids are degraded much more slowly. Thus, ClpA recognizes an N-terminal signal in RepA beginning in the vicinity of amino acids 10-15. Moreover, peptides corresponding to RepA amino acids 4-13 and 1-15 inhibit interactions between ClpA and RepA. We constructed fusions of RepA and green fluorescent protein, a protein not recognized by ClpA, and found that the N-terminal 15 amino acids of RepA are sufficient to target the fusion protein for degradation by ClpAP. However, fusion proteins containing 46 or 70 N-terminal amino acids of RepA are degraded more efficiently in vitro and are noticeably stabilized in vivo in clpADelta and clpPDelta strains compared with wild type.

Heptameric ring structure of the heat-shock protein ClpB, a protein-activated ATPase in Escherichia coli

The heat-shock protein ClpB is a protein-activated ATPase that is essential for survival of Escherichia coli at high temperatures. ClpB has also recently been suggested to function as a chaperone in reactivation of aggregated proteins. In addition, the clpB gene has been shown to contain two translational initiation sites and therefore encode two polypeptides of different size. To determine the structural organization of ClpB, the ClpB proteins were subjected to chemical cross-linking analysis and electron microscopy. The average images of the ClpB proteins with end-on orientation revealed a seven-membered, ring-shaped structure with a central cavity. Their side-on view showed a two-layered structure with an equal distribution of mass across the equatorial plane of the complex. Since the ClpB subunit has two large regions containing consensus sequences for nucleotide binding, each layer of the ClpB heptamer appears to represent the side projection of one of the major domains arranged on a ring. In the absence of salt and ATP, the ClpB proteins showed a high tendency to form a heptamer. However, they dissociated into various species of oligomers with smaller sizes, depending on salt concentration. Above 0.2 M NaCl, the ClpB proteins behaved most likely as a monomer in the absence of ATP, but assembled into a heptamer in its presence. Furthermore, mutations of the first ATP-binding site, but not the second site, prevented the ATP-dependent oligomerization of the ClpB proteins in the presence of 0.3 M NaCl. These results indicate that ClpB has a heptameric ring-shaped structure with a central cavity and this structural organization requires ATP binding to the first nucleotide-binding site localized to the N-terminal half of the ATPase.

Molecular basis for interactions of the DnaK chaperone with substrates

Hsp70 chaperones assist a large variety of protein folding processes in the cell by transient association with short peptide segments of proteins. The substrate binding and release cycle is driven by the switching between the low affinity ATP bound state and the high affinity ADP bound state of Hsp70. Considerable progress has been made recently by the identification of in vivo substrates for the Escherichia coli homolog, DnaK, and the molecular mechanisms which govern the DnaK-substrate interactions. Here we review the processes that generate DnaK substrates in vivo and the properties of these substrates, and we describe insights gained from structural and kinetic analysis of DnaK-substrate interaction.

Protein binding and unfolding by the chaperone ClpA and degradation by the protease ClpAP

ClpA, a bacterial member of the Clp/Hsp100 chaperone family, is an ATP-dependent molecular chaperone and the regulatory component of the ATP-dependent ClpAP protease. To study the mechanism of binding and unfolding of proteins by ClpA and translocation to ClpP, we used as a model substrate a fusion protein that joined the ClpA recognition signal from RepA to green fluorescent protein (GFP). ClpAP degrades the fusion protein in vivo and in vitro. The substrate binds specifically to ClpA in a reaction requiring ATP binding but not hydrolysis. Binding alone is not sufficient to destabilize the native structure of the GFP portion of the fusion protein. Upon ATP hydrolysis the GFP fusion protein is unfolded, and the unfolded intermediate can be sequestered by ClpA if a nonhydrolyzable analog is added to displace ATP. ATP is required for release. We found that although ClpA is unable to recognize native proteins lacking recognition signals, including GFP and rhodanese, it interacts with those same proteins when they are unfolded. Unfolded GFP is held in a nonnative conformation while associated with ClpA and its release requires ATP hydrolysis. Degradation of unfolded untagged proteins by ClpAP requires ATP even though the initial ATP-dependent unfolding reaction is bypassed. These results suggest that there are two ATP-requiring steps: an initial protein unfolding step followed by translocation of the unfolded protein to ClpP or in some cases release from the complex.

Size-dependent disaggregation of stable protein aggregates by the DnaK chaperone machinery

Classic in vitro studies show that the Hsp70 chaperone system from Escherichia coli (DnaK-DnaJ-GrpE, the DnaK system) can bind to proteins, prevent aggregation, and promote the correct refolding of chaperone-bound polypeptides into native proteins. However, little is known about how the DnaK system handles proteins that have already aggregated. In this study, glucose-6-phosphate dehydrogenase was used as a model system to generate stable populations of protein aggregates comprising controlled ranges of particle sizes. The DnaK system recognized the glucose-6-phosphate dehydrogenase aggregates as authentic substrates and specifically solubilized and refolded the protein into a native enzyme. The efficiency of disaggregation by the DnaK system was high with small aggregates, but the efficiency decreased as the size of the aggregates increased. High folding efficiency was restored by either excess DnaK or substoichiometric amounts of the chaperone ClpB. We suggest a mechanism whereby the DnaK system can readily solubilize small aggregates and refold them into active proteins. With large aggregates, however, the binding sites for the DnaK system had to be dynamically exposed with excess DnaK or the catalytic action of ClpB and ATP. Disaggregation by the DnaK machinery in the cell can solubilize early aggregates that formed accidentally during chaperone-assisted protein folding or that escaped the protection of "holding" chaperones during stress.

The Escherichia coli heat shock protein ClpB restores acquired thermotolerance to a cyanobacterial clpB deletion mutant

In both prokaryotes and eukaryotes, the heat shock protein ClpB functions as a molecular chaperone and plays a key role in resisting high temperature stress. ClpB is important for the development of thermotolerance in yeast and cyanobacteria but apparently not in Escherichia coli. We undertook a complementation study to investigate whether the ClpB protein from E coli (EcClpB) differs functionally from its cyanobacterial counterpart in the unicellular cyanobacterium Synechococcus sp. PCC 7942. The EcClpB protein is 56% identical to its ClpB1 homologue in Synechococcus. A plasmid construct was prepared containing the entire E coli clpB gene under the control of the Synechococcus clpB1 promoter. This construct was transformed into a Synechococcus clpB1 deletion strain (deltaclpB1) and integrated into a phenotypically neutral site of the chromosome. The full-length EcClpB protein (EcClpB-93) was induced in the transformed Synechococcus strain during heat shock as well as the smaller protein (EcClpB-79) that arises from a second translational start inside the single clpB message. Using cell survival measurements we show that the EcClpB protein can complement the Synechococcus deltaclpB1 mutant and restore its ability to develop thermotolerance. We also demonstrate that both EcClpB-93 and -79 appear to contribute to the degree of acquired thermotolerance restored to the Synechococcus complementation strains.

ClpB and HtpG facilitate de novo protein folding in stressed Escherichia coli cells

DnaK-DnaJ-GrpE and GroEL-GroES are the best-characterized molecular chaperone systems in the cytoplasm of Escherichia coli. A number of additional proteins, including ClpA, ClpB, HtpG and IbpA/B, act as molecular chaperones in vitro, but their function in cellular protein folding remains unclear. Here, we examine how these chaperones influence the folding of newly synthesized recombinant proteins under heat-shock conditions. We show that the absence of either CIpB or HtpG at 42 degrees C leads to increased aggregation of preS2-beta-galactosidase, a fusion protein whose folding depends on DnaK-DnaJ-GrpE, but not GroEL-GroES. However, only the deltaclpB mutation is deleterious to the folding of homodimeric Rubisco and cMBP, two proteins requiring the GroEL-GroES chaperonins to reach a proper conformation. Null mutations in clpA or the ibpAB operon do not affect the folding of these model substrates. Overexpression of ClpB, HtpG, IbpA/B or ClpA does not suppress inclusion body formation by the aggregation-prone protein preS2-S'-beta-galactosidase in wild-type cells or alleviate recombinant protein misfolding in dnaJ259, grpE280 or groES30 mutants. By contrast, higher levels of DnaK-DnaJ, but not GroEL-GroES, restore efficient folding in deltaclpB cells. These results indicate that ClpB, and to a lesser extent HtpG, participate in de novo protein folding in mildly stressed E. coli cells, presumably by expanding the ability of the DnaK-DnaJ-GrpE team to interact with newly synthesized polypeptides.

Heat-inactivated proteins managed by DnaKJ-GrpE-ClpB chaperones are released as a chaperonin-recognizable non-native form

Chaperones of Thermus thermophilus cooperate in reactivation of heat-inactivated proteins. The protein, inactivated at a high temperature in a TDnaKJ-GrpE set, recovered its activity during subsequent incubation with TClpB at moderate temperature (Motohashi, K., Watanabe, Y., Yohda, M., and Yoshida, M. (1999) Proc. Natl. Acad. Sci. U. S. A. 96, 7184-7189). Here, we report that the addition of chaperonin (Tcpn) at moderate temperature improves the yield of the TDnaKJ-GrpE-ClpB-dependent reactivation. The trap-Tcpn, which binds substrate protein but does not release it, inhibits reactivation severely. Maximum recovery is gained at sub-stoichiometric amounts of each component of TDnaKJ, TGrpE, and TClpB relative to the substrate monomer. These observations indicate that, driven by ATP hydrolysis, TDnaKJ-GrpE-ClpB chaperones catalytically cooperate and release heat-inactivated protein as a non-native, chaperonin-recognizable folding intermediate.

Mutants of Arabidopsis thaliana defective in the acquisition of tolerance to high temperature stress

The ability of organisms to acquire thermotolerance to normally lethal high temperatures is an ancient and conserved adaptive response. However, knowledge of cellular factors essential to this response is limited. Acquisition of thermotolerance is likely to be of particular importance to plants that experience daily temperature fluctuations and are unable to escape to more favorable environments. We developed a screen, based on hypocotyl elongation, for mutants of Arabidopsis thaliana that are unable to acquire thermotolerance to high-temperature stress and have defined four separate genetic loci, hot1-4, required for this process. hot1 was found to have a mutation in the heat shock protein 101 (Hsp101) gene, converting a conserved Glu residue in the second ATP-binding domain to a Lys residue, a mutation that is predicted to compromise Hsp101 ATPase activity. In addition to exhibiting a thermotolerance defect as assayed by hypocotyl elongation, 10-day-old hot1 seedlings were also unable to acquire thermotolerance, and hot1 seeds had greatly reduced basal thermotolerance. Complementation of hot1 plants by transformation with wild-type Hsp101 genomic DNA restored hot1 plants to the wild-type phenotype. The hot mutants are the first mutants defective in thermotolerance that have been isolated in a higher eukaryote, and hot1 represents the first mutation in an Hsp in any higher plant. The phenotype of hot1 also provides direct evidence that Hsp101, which is required for thermotolerance in bacteria and yeast, is also essential for thermotolerance in a complex eukaryote.

Protein folding and unfolding by Escherichia coli chaperones and chaperonins

The folding of proteins from their initial unstructured state to their mature form has long been known to be promoted by other proteins known as chaperones and chaperonins. Recent biochemical and structural discoveries have provided dramatic insight into how these folding proteins work. This review will discuss these findings and suggest future experimental directions.

Posttranslational quality control: folding, refolding, and degrading proteins

Polypeptides emerging from the ribosome must fold into stable three-dimensional structures and maintain that structure throughout their functional lifetimes. Maintaining quality control over protein structure and function depends on molecular chaperones and proteases, both of which can recognize hydrophobic regions exposed on unfolded polypeptides. Molecular chaperones promote proper protein folding and prevent aggregation, and energy-dependent proteases eliminate irreversibly damaged proteins. The kinetics of partitioning between chaperones and proteases determines whether a protein will be destroyed before it folds properly. When both quality control options fail, damaged proteins accumulate as aggregates, a process associated with amyloid diseases.