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

ClpL is a functionally active tetradecameric AAA+ chaperone, distinct from hexameric/dodecameric ones

AAA+ (ATPases associated with diverse cellular activities) chaperones are involved in a plethora of cellular activities to ensure protein homeostasis. The function of AAA+ chaperones is mostly modulated by their hexameric/dodecameric quaternary structures. Here we report the structural and biochemical characterizations of a tetradecameric AAA+ chaperone, ClpL from Streptococcus pneumoniae. ClpL exists as a tetradecamer in solution in the presence of ATP. The cryo-EM structure of ClpL at 4.5 Å resolution reveals a striking tetradecameric arrangement. Solution structures of ClpL derived from small-angle X-ray scattering data suggest that the tetradecameric ClpL could assume a spiral conformation found in active hexameric/dodecameric AAA+ chaperone structures. Vertical positioning of the middle domain accounts for the head-to-head arrangement of two heptameric rings. Biochemical activity assays with site-directed mutagenesis confirmed the critical roles of residues both in the integrity of the tetradecameric arrangement and activities of ClpL. Non-conserved Q321 and R670 are crucial in the heptameric ring assembly of ClpL. These results establish that ClpL is a functionally active tetradecamer, clearly distinct from hexameric/dodecameric AAA+ chaperones.

Hexameric assembly of the AAA+ protein McrB is necessary for GTPase activity

McrBC is one of the three modification-dependent restriction enzymes encoded by the Escherichia coli K12 chromosome. Amongst restriction enzymes, McrBC and its close homologues are unique in employing the AAA+ domain for GTP hydrolysis-dependent activation of DNA cleavage. The GTPase activity of McrB is stimulated by the endonuclease subunit McrC. It had been reported previously that McrB and McrC subunits oligomerise together into a high molecular weight species. Here we conclusively demonstrate using size exclusion chromatography coupled multi-angle light scattering (SEC-MALS) and images obtained by electron cryomicroscopy that McrB exists as a hexamer in solution. Furthermore, based on SEC-MALS and SAXS analyses of McrBC and the structure of McrB, we propose that McrBC is a complex of two McrB hexamers bridged by two subunits of McrC, and that the complete assembly of this complex is integral to its enzymatic activity. We show that the nucleotide-dependent oligomerisation of McrB precedes GTP hydrolysis. Mutational studies show that, unlike other AAA+ proteins, the catalytic Walker B aspartate is required for oligomerisation.

Dynamic structural states of ClpB involved in its disaggregation function

The ATP-dependent bacterial protein disaggregation machine, ClpB belonging to the AAA+ superfamily, refolds toxic protein aggregates into the native state in cooperation with the cognate Hsp70 partner. The ring-shaped hexamers of ClpB unfold and thread its protein substrate through the central pore. However, their function-related structural dynamics has remained elusive. Here we directly visualize ClpB using high-speed atomic force microscopy (HS-AFM) to gain a mechanistic insight into its disaggregation function. The HS-AFM movies demonstrate massive conformational changes of the hexameric ring during ATP hydrolysis, from a round ring to a spiral and even to a pair of twisted half-spirals. HS-AFM observations of Walker-motif mutants unveil crucial roles of ATP binding and hydrolysis in the oligomer formation and structural dynamics. Furthermore, repressed and hyperactive mutations result in significantly different oligomeric forms. These results provide a comprehensive view for the ATP-driven oligomeric-state transitions that enable ClpB to disentangle protein aggregates.

The bacterial protein disaggregation machine ClpB uses ATP to generate mechanical force to unfold and thread its protein substrates. Here authors visualize the ClpB ring using high-speed atomic force microscopy and capture conformational changes of the hexameric ring during the ATPase reaction.

Phylogenetic analysis predicts structural divergence for proteobacterial ClpC proteins

Regulated proteolysis is required in all organisms for the removal of misfolded or degradation-tagged protein substrates in cellular quality control pathways. The molecular machines that catalyze this process are known as ATP-dependent proteases with examples that include ClpAP and ClpCP. Clp/Hsp100 subunits form ring-structures that couple the energy of ATP binding and hydrolysis to protein unfolding and subsequent translocation of denatured protein into the compartmentalized ClpP protease for degradation. Copies of the clpA, clpC, clpE, clpK, and clpL genes are present in all characterized bacteria and their gene products are highly conserved in structure and function. However, the evolutionary relationship between these proteins remains unclear. Here we report a comprehensive phylogenetic analysis that suggests divergent evolution yielded ClpA from an ancestral ClpC protein and that ClpE/ClpL represent intermediates between ClpA/ClpC. This analysis also identifies a group of proteobacterial ClpC proteins that are likely not functional in regulated proteolysis. Our results strongly suggest that bacterial ClpC proteins should not be assumed to all function identically due to the structural differences identified here.

Comparative Analysis of the Structure and Function of AAA+ Motors ClpA, ClpB, and Hsp104: Common Threads and Disparate Functions

Cellular proteostasis involves not only the expression of proteins in response to environmental needs, but also the timely repair or removal of damaged or unneeded proteins. AAA+ motor proteins are critically involved in these pathways. Here, we review the structure and function of AAA+ proteins ClpA, ClpB, and Hsp104. ClpB and Hsp104 rescue damaged proteins from toxic aggregates and do not partner with any protease. ClpA functions as the regulatory component of the ATP dependent protease complex ClpAP, and also remodels inactive RepA dimers into active monomers in the absence of the protease. Because ClpA functions both with and without a proteolytic component, it is an ideal system for developing strategies that address one of the major challenges in the study of protein remodeling machines: how do we observe a reaction in which the substrate protein does not undergo covalent modification? Here, we review experimental designs developed for the examination of polypeptide translocation catalyzed by the AAA+ motors in the absence of proteolytic degradation. We propose that transient state kinetic methods are essential for the examination of elementary kinetic mechanisms of these motor proteins. Furthermore, rigorous kinetic analysis must also account for the thermodynamic properties of these complicated systems that reside in a dynamic equilibrium of oligomeric states, including the biologically active hexamer.

Assessing heterogeneity in oligomeric AAA+ machines

ATPases Associated with various cellular Activities (AAA+ ATPases) are molecular motors that use the energy of ATP binding and hydrolysis to remodel their target macromolecules. The majority of these ATPases form ring-shaped hexamers in which the active sites are located at the interfaces between neighboring subunits. Structural changes initiate in an active site and propagate to distant motor parts that interface and reshape the target macromolecules, thereby performing mechanical work. During the functioning cycle, the AAA+ motor transits through multiple distinct states. Ring architecture and placement of the catalytic sites at the intersubunit interfaces allow for a unique level of coordination among subunits of the motor. This in turn results in conformational differences among subunits and overall asymmetry of the motor ring as it functions. To date, a large amount of structural information has been gathered for different AAA+ motors, but even for the most characterized of them only a few structural states are known and the full mechanistic cycle cannot be yet reconstructed. Therefore, the first part of this work will provide a broad overview of what arrangements of AAA+ subunits have been structurally observed focusing on diversity of ATPase oligomeric ensembles and heterogeneity within the ensembles. The second part of this review will concentrate on methods that assess structural and functional heterogeneity among subunits of AAA+ motors, thus bringing us closer to understanding the mechanism of these fascinating molecular motors.

Examination of the dynamic assembly equilibrium for E. coli ClpB

Escherichia coli ClpB is a heat shock protein that belongs to the AAA+ protein superfamily. Studies have shown that ClpB and its homologue in yeast, Hsp104, can disrupt protein aggregates in vivo. It is thought that ClpB requires binding of nucleoside triphosphate to assemble into hexameric rings with protein binding activity. In addition, it is widely assumed that ClpB is uniformly hexameric in the presence of nucleotides. Here we report, in the absence of nucleotide, that increasing ClpB concentration leads to ClpB hexamer formation, decreasing NaCl concentration stabilizes ClpB hexamers, and the ClpB assembly reaction is best described by a monomer, dimer, tetramer, hexamer equilibrium under the three salt concentrations examined. Further, we found that ClpB oligomers exhibit relatively fast dissociation on the time scale of sedimentation. We anticipate our studies on ClpB assembly to be a starting point to understand how ClpB assembly is linked to the binding and disaggregation of denatured proteins.

Disaggregases, molecular chaperones that resolubilize protein aggregates

The process of folding is a seminal event in the life of a protein, as it is essential for proper protein function and therefore cell physiology. Inappropriate folding, or misfolding, can not only lead to loss of function, but also to the formation of protein aggregates, an insoluble association of polypeptides that harm cell physiology, either by themselves or in the process of formation. Several biological processes have evolved to prevent and eliminate the existence of non-functional and amyloidogenic aggregates, as they are associated with several human pathologies. Molecular chaperones and heat shock proteins are specialized in controlling the quality of the proteins in the cell, specifically by aiding proper folding, and dissolution and clearance of already formed protein aggregates. The latter is a function of disaggregases, mainly represented by the ClpB/Hsp104 subfamily of molecular chaperones, that are ubiquitous in all organisms but, surprisingly, have no orthologs in the cytosol of metazoan cells. This review aims to describe the characteristics of disaggregases and to discuss the function of yeast Hsp104, a disaggregase that is also involved in prion propagation and inheritance.

Chaperone-assisted protein aggregate reactivation: Different solutions for the same problem

The oligomeric AAA+ chaperones Hsp104 in yeast and ClpB in bacteria are responsible for the reactivation of aggregated proteins, an activity essential for cell survival during severe stress. The protein disaggregase activity of these members of the Hsp100 family is linked to the activity of chaperones from the Hsp70 and Hsp40 families. The precise mechanism by which these proteins untangle protein aggregates remains unclear. Strikingly, Hsp100 proteins are not present in metazoans. This does not mean that animal cells do not have a disaggregase activity, but that this activity is performed by the Hsp70 system and a representative of the Hsp110 family instead of a Hsp100 protein. This review describes the actual view of Hsp100-mediated aggregate reactivation, including the ATP-induced conformational changes associated with their disaggregase activity, the dynamics of the oligomeric assembly that is regulated by its ATPase cycle and the DnaK system, and the tight allosteric coupling between the ATPase domains within the hexameric ring complexes. The lack of homologs of these disaggregases in metazoans has suggested that they might be used as potential targets to develop antimicrobials. The current knowledge of the human disaggregase machinery and the role of Hsp110 are also discussed.

Escherichia coli ClpB is a non-processive polypeptide translocase

Escherichia coli caseinolytic protease (Clp)B is a hexameric AAA+ [expanded superfamily of AAA (ATPase associated with various cellular activities)] enzyme that has the unique ability to catalyse protein disaggregation. Such enzymes are essential for proteome maintenance. Based on structural comparisons to homologous enzymes involved in ATP-dependent proteolysis and clever protein engineering strategies, it has been reported that ClpB translocates polypeptide through its axial channel. Using single-turnover fluorescence and anisotropy experiments we show that ClpB is a non-processive polypeptide translocase that catalyses disaggregation by taking one or two translocation steps followed by rapid dissociation. Using single-turnover FRET experiments we show that ClpB containing the IGL loop from ClpA does not translocate substrate through its axial channel and into ClpP for proteolytic degradation. Rather, ClpB containing the IGL loop dysregulates ClpP leading to non-specific proteolysis reminiscent of ADEP (acyldepsipeptide) dysregulation. Our results support a molecular mechanism where ClpB catalyses protein disaggregation by tugging and releasing exposed tails or loops.

Sedimentation Equilibrium Analysis of ClpB Self-Association in Diluted and Crowded Solutions

ClpB belongs to the Hsp100 family of ring-forming heat-shock proteins involved in degradation of unfolded/misfolded proteins and in reactivation of protein aggregates. ClpB monomers reversibly associate to form the hexameric molecular chaperone that, together with the DnaK system, has the ability to disaggregate stress-denatured proteins. Here, we summarize the use of sedimentation equilibrium approaches, complemented with sedimentation velocity and composition-gradient static light scattering measurements, to study the self-association properties of ClpB in dilute and crowded solutions. As the functional unit of ClpB is the hexamer, we study the effect of environmental factors, i.e., ionic strength and natural ligands, in the association equilibrium of ClpB as well as the role of the flexible N-terminal and M domains of the protein in the self-association process. The application of the nonideal sedimentation equilibrium technique to measure the effects of volume exclusion, reproducing in part the natural crowded conditions inside a cell, on the self-association and on the stability of the oligomeric species of the disaggregase will be described. Finally, the biochemical and physiological implications of these studies and future experimental challenges to eventually reconstitute minimal disaggregating machineries will be discussed.

A 1-Cys Peroxiredoxin from a Thermophilic Archaeon Moonlights as a Molecular Chaperone to Protect Protein and DNA against Stress-Induced Damage

Peroxiredoxins (Prxs) act against hydrogen peroxide (H2O2), organic peroxides, and peroxynitrite. Thermococcus kodakaraensis KOD1, an anaerobic archaeon, contains many antioxidant proteins, including three Prxs (Tk0537, Tk0815, and Tk1055). Only Tk0537 has been found to be induced in response to heat, osmotic, and oxidative stress. Tk0537 was found to belong to a 1-Cys Prx6 subfamily based on sequence analysis and was named 1-Cys TkPrx. Using gel filtration chromatography, electron microscopy, and blue-native polyacrylamide gel electrophoresis, we observed that 1-Cys TkPrx exhibits oligomeric forms with reduced peroxide reductase activity as well as decameric and dodecameric forms that can act as molecular chaperones by protecting both proteins and DNA from oxidative stress. Mutational analysis showed that a cysteine residue at the N-terminus (Cys46) was responsible for the peroxide reductase activity, and cysteine residues at the C-terminus (Cys205 and Cys211) were important for oligomerization. Based on our results, we propose that interconversion between different oligomers is important for regulating the different functions of 1-Cys TkPrx.

ClpL is a chaperone without auxiliary factors

Caseinolytic protease L (ClpL) is a member of the heat shock protein (Hsp) 100 family, which is found mostly in Gram-positive bacteria. Here, ClpL, a major HSP in Streptococcus pneumoniae (pneumococcus), was biochemically characterized in vitro. Recombinant ClpL shows nucleotide hydrolase, refolding, holdase and disaggregation activity using either Mg(2+) or Mn(2+) and does not require the DnaK system for chaperone activity. ClpL exhibits two features distinct from other HSP100 family proteins: (a) Mn(2+) enhances hydrolase activity, as well as chaperone activity; and (b) NTPase activity. ClpL forms a hexamer in the presence of ADP, ATP and ATP-γ-S. Mutational analysis using double-mutant proteins mutated at the two Walker A motifs (K127A/T128A and K458A/T459A) revealed that both nucleotide-binding domains are involved in chaperone activity, ATP hydrolase activity and hexamerization. Overall, pneumococcal ClpL is a unique Mn(2+) -dependent Hsp100 family member that has chaperone activity without other co-chaperones.

The role of bacterial enhancer binding proteins as specialized activators of σ54-dependent transcription

Bacterial enhancer binding proteins (bEBPs) are transcriptional activators that assemble as hexameric rings in their active forms and utilize ATP hydrolysis to remodel the conformation of RNA polymerase containing the alternative sigma factor σ(54). We present a comprehensive and detailed summary of recent advances in our understanding of how these specialized molecular machines function. The review is structured by introducing each of the three domains in turn: the central catalytic domain, the N-terminal regulatory domain, and the C-terminal DNA binding domain. The role of the central catalytic domain is presented with particular reference to (i) oligomerization, (ii) ATP hydrolysis, and (iii) the key GAFTGA motif that contacts σ(54) for remodeling. Each of these functions forms a potential target of the signal-sensing N-terminal regulatory domain, which can act either positively or negatively to control the activation of σ(54)-dependent transcription. Finally, we focus on the DNA binding function of the C-terminal domain and the enhancer sites to which it binds. Particular attention is paid to the importance of σ(54) to the bacterial cell and its unique role in regulating transcription.

A tightly regulated molecular toggle controls AAA+ disaggregase

The ring-forming AAA+ protein ClpB cooperates with the DnaK chaperone system to refold aggregated proteins in Escherichia coli. The M domain, a ClpB-specific coiled-coil structure with two wings, motif 1 and motif 2, is essential to disaggregation, but the positioning and mechanistic role of M domains in ClpB hexamers remain unresolved. We show that M domains nestle at the ClpB ring surface, with both M-domain motifs contacting the first ATPase domain (AAA-1). Both wings contribute to maintaining a repressed ClpB activity state. Motif 2 docks intramolecularly to AAA-1 to regulate ClpB unfolding power, and motif 1 contacts a neighboring AAA-1 domain. Mutations that stabilize motif 2 docking repress ClpB, whereas destabilization leads to derepressed ClpB activity with greater unfolding power that is toxic in vivo. Our results underline the vital nature of tight ClpB activity control and elucidate a regulated M-domain toggle control mechanism.

Mapping the road to recovery: the ClpB/Hsp104 molecular chaperone

The AAA(+)-ATPases are a family of molecular motors which have been seconded into a plethora of cellular tasks. One subset, the Hsp100 molecular chaperones, are general protein remodellers that help to maintain the integrity of the cellular proteome by means of protein destruction or resurrection. In this review we focus on one family of Hsp100s, the homologous ClpB and Hsp104 molecular chaperones that convey thermotolerance by resolubilising and rescuing proteins from aggregates. We explore how the nucleotide binding and hydrolysis properties at the twelve nucleotide-binding domains of these hexameric rings are coupled to protein disaggregation, highlighting similarities and differences between ClpB and Hsp104.

Orientation of the amino-terminal domain of ClpB affects the disaggregation of the protein

ClpB/Hsp104 efficiently reactivates protein aggregates in cooperation with the DnaK/Hsp70 system. As a member of the AAA+ protein family (i.e. an expanded superfamily of ATPases associated with diverse cellular activities), ClpB forms a ring-shaped hexamer in an ATP-dependent manner. A protomer of ClpB consists of an N-terminal domain (NTD), an AAA+ module, a middle domain and another AAA+ module. In the crystal structures, the NTDs point to two different directions relative to other domains and are not visible in the single-particle cryo-electron microscopy reconstruction, suggesting that the NTD is highly mobile. In the present study, we generated mutants in which the NTD was anchored to other domain by disulfide cross-linking and compared several aspects of ClpB function between the reduced and oxidized mutants, using the wild-type and NTD-truncated ClpB (ClpBΔN) as references. In their oxidized form, the mutants and wild-type bind casein with a similar affinity, although the affinity of ClpBΔN for casein was significantly low. However, the extent of casein-induced stimulation of ATPase, the rate of substrate threading and the efficiency of protein disaggregation of these mutants were all lower than those of the wild-type but similar to those of ClpBΔN. These results indicate that the NTD supports the substrate binding of ClpB and that its conformational shift assists the threading and disaggregation of substrate proteins.

On the design of broad based screening assays to identify potential pharmacological chaperones of protein misfolding diseases

Correcting aberrant folds that develop during protein folding disease states is now an active research endeavor that is attracting increasing attention from both academic and industrial circles. One particular approach focuses on developing or identifying small molecule correctors or pharmacological chaperones that specifically stabilize the native fold. Unfortunately, the limited screening platforms available to rapidly identify or validate potential drug candidates are usually inadequate or slow because the folding disease proteins in question are often transiently folded and/or aggregation-prone, complicating and/or interfering with the assay outcomes. In this review, we outline and discuss the numerous platform options currently being employed to identify small molecule therapeutics for folding diseases. Finally, we describe a new stability screening approach that is broad based and is easily applicable toward a very large number of both common and rare protein folding diseases. The label free screening method described herein couples the promiscuity of the GroEL binding to transient aggregation-prone hydrophobic folds with surface plasmon resonance enabling one to rapidly identify potential small molecule pharmacological chaperones.

AAA ATPase p529 of Acidianus two-tailed virus ATV and host receptor recognition

The two structural domains of p529, a predicted AAA ATPase of Acidianus two-tailed virus (ATV), were expressed and purified. The N-terminal domain was demonstrated by loss-of-function mutations to carry ATPase activity with a temperature optimum of 60°C. This domain also showed DNA binding activity that was stronger for the whole protein and was weakened in the presence of ATP. The C-terminal domain exhibits Mg(2+)-dependent endonuclease activity that was eliminated by site-directed mutagenesis at a conserved catalytic PD…D/ExK motif. p529 pull-down experiments with cell extracts of Sulfolobus solfataricus demonstrated a specific interaction with Sso1273, corresponding to OppA(Ss), an N-linked glycoprotein that specifically binds oligopeptides. The sso1273 gene lies in an operon encoding an oligopeptide/dipeptide ABC transporter system. It is proposed that p529 is involved in ATV-host cell receptor recognition and possibly the endonuclease activity is required for cleavage of the circular viral DNA prior to cell entry.

Structure and function of the AAA+ nucleotide binding pocket

Members of the diverse superfamily of AAA+ proteins are molecular machines responsible for a wide range of essential cellular processes. In this review we summarise structural and functional data surrounding the nucleotide binding pocket of these versatile complexes. Protein Data Bank (PDB) structures of closely related AAA+ ATPase are overlaid and biologically relevant motifs are displayed. Interactions between protomers are illustrated on the basis of oligomeric structures of each AAA+ subgroup. The possible role of conserved motifs in the nucleotide binding pocket is assessed with regard to ATP binding and hydrolysis, oligomerisation and inter-subunit communication. Our comparison indicates that in particular the roles of the arginine finger and sensor 2 residues differ subtly between AAA+ subgroups, potentially providing a means for functional diversification.

Allosteric communication between the nucleotide binding domains of caseinolytic peptidase B

ClpB is a hexameric chaperone that solubilizes and reactivates protein aggregates in cooperation with the Hsp70/DnaK chaperone system. Each of the identical protein monomers contains two nucleotide binding domains (NBD), whose ATPase activity must be coupled to exert on the substrate the mechanical work required for its reactivation. However, how communication between these sites occurs is at present poorly understood. We have studied herein the affinity of each of the NBDs for nucleotides in WT ClpB and protein variants in which one or both sites are mutated to selectively impair nucleotide binding or hydrolysis. Our data show that the affinity of NBD2 for nucleotides (K(d) = 3-7 μm) is significantly higher than that of NBD1. Interestingly, the affinity of NBD1 depends on nucleotide binding to NBD2. Binding of ATP, but not ADP, to NBD2 increases the affinity of NBD1 (the K(d) decreases from ≈160-300 to 50-60 μm) for the corresponding nucleotide. Moreover, filling of the NBD2 ring with ATP allows the cooperative binding of this nucleotide and substrates to the NBD1 ring. Data also suggest that a minimum of four subunits cooperate to bind and reactivate two different aggregated protein substrates.

Biochemical characterization of glyceraldehyde-3-phosphate dehydrogenase from Thermococcus kodakarensis KOD1

Glyceraldehyde-3-phosphate dehydrogenase (GAPDH) plays an essential role in glycolysis by catalyzing the conversion of D-glyceraldehyde 3-phosphate (D-G3P) to 1,3-diphosphoglycerate using NAD(+) as a cofactor. In this report, the GAPDH gene from the hyperthermophilic archaeon Thermococcus kodakarensis KOD1 (GAPDH-tk) was cloned and the protein was purified to homogeneity. GAPDH-tk exists as a homotetramer with a native molecular mass of 145 kDa; the subunit molecular mass was 37 kDa. GAPDH-tk is a thermostable protein with a half-life of 5 h at 80-90°C. The apparent K (m) values for NAD(+) and D-G3P were 77.8 ± 7.5 μM and 49.3 ± 3.0 μM, respectively, with V (max) values of 45.1 ± 0.8 U/mg and 59.6 ± 1.3 U/mg, respectively. Transmission electron microscopy (TEM) and image processing confirmed that GAPDH-tk has a tetrameric structure. Interestingly, GAPDH-tk migrates as high molecular mass forms (~232 kDa and ~669 kDa) in response to oxidative stress.

A quantitative analysis of the effect of nucleotides and the M domain on the association equilibrium of ClpB

ClpB is a hexameric molecular chaperone that, together with the DnaK system, has the ability to disaggregate stress-denatured proteins. The hexamer is a highly dynamic complex, able to reshuffle subunits. To further characterize the biological implications of the ClpB oligomerization state, the association equilibrium of the wild-type (wt) protein and of two deletion mutants, which lack part or the whole M domain, was quantitatively analyzed under different experimental conditions, using several biophysical [analytical ultracentrifugation, composition-gradient (CG) static light scattering, and circular dichroism] and biochemical (ATPase and chaperone activity) methods. We have found that (i) ClpB self-associates from monomers to form hexamers and higher-order oligomers that have been tentatively assigned to dodecamers, (ii) oligomer dissociation is not accompanied by modifications of the protein secondary structure, (iii) the M domain is engaged in intersubunit interactions that stabilize the protein hexamer, and (iv) the nucleotide-induced rearrangement of ClpB affects the protein oligomeric core, in addition to the proposed radial extension of the M domain. The difference in the stability of the ATP- and ADP-bound states [ΔΔG(ATP-ADP) = -10 kJ/mol] might explain how nucleotide exchange promotes the conformational change of the protein particle that drives its functional cycle.

An archaeal NADH oxidase causes damage to both proteins and nucleic acids under oxidative stress

NADH oxidases (NOXs) catalyze the two-electron reduction of oxygen to H2O2 or four-electron reduction of oxygen to H2O. In this report, we show that an NADH oxidase from Thermococcus profundus (NOXtp) displays two forms: a native dimeric protein under physiological conditions and an oxidized hexameric form under oxidative stress. Native NOXtp displays high NADH oxidase activity, and oxidized NOXtp can accelerate the aggregation of partially unfolded proteins. The aggregates formed by NOXtp have characteristics similar to beta-amyloid and Lewy bodies in neurodegenerative diseases, including an increase of beta-sheet content. Oxidized NOXtp can also bind nucleic acids and cause their degradation by oxidizing NADH to produce H2O2. Furthermore, Escherichia coli cells expressing NOXtp are less viable than cells not expressing NOXtp after treatment with H2O2. As NOXtp shares similar features with eukaryotic cell death isozymes and life may have originated from hyperthermophiles, we suggest that NOXtp may be an ancestor of cell death proteins.

Synergistic cooperation between two ClpB isoforms in aggregate reactivation

Bacterial AAA+ ATPase ClpB cooperates with DnaK during reactivation of aggregated proteins. The ClpB-mediated disaggregation is linked to translocation of polypeptides through the channel in the oligomeric ClpB. Two isoforms of ClpB are produced in vivo: the full-length ClpB95 and ClpB80, which does not contain the substrate-interacting N-terminal domain. The biological role of the truncated isoform ClpB80 is unknown. We found that resolubilization of aggregated proteins in Escherichia coli after heat shock and reactivation of aggregated proteins in vitro and in vivo occurred at higher rates in the presence of ClpB95 with ClpB80 than with ClpB95 or ClpB80 alone. Combined amounts of ClpB95 and ClpB80 bound to aggregated substrates were similar to the amounts of either ClpB95 or ClpB80 bound to the substrates in the absence of another isoform. The ATP hydrolysis rate of ClpB95 with ClpB80, which is linked to the rate of substrate translocation, was not higher than the rates measured for the isolated ClpB95 or ClpB80. We postulate that a reaction step that takes place after substrate binding to ClpB and precedes substrate translocation is rate-limiting during aggregate reactivation, and its efficiency is enhanced in the presence of both ClpB isoforms. Moreover, we found that ClpB95 and ClpB80 form hetero-oligomers, which are similar in size to the homo-oligomers of ClpB95 or ClpB80. Thus, the mechanism of functional cooperation of the two isoforms of ClpB may be linked to their heteroassociation. Our results suggest that the functionality of other AAA+ ATPases may be also optimized by interaction and synergistic cooperation of their isoforms.

Hexameric ring structure of a thermophilic archaeon NADH oxidase that produces predominantly H2O

An NADH oxidase (NOX) was cloned from the genome of Thermococcus profundus (NOXtp) by genome walking, and the encoded protein was purified to homogeneity after expression in Escherichia coli. Subsequent analyses showed that it is an FAD-containing protein with a subunit molecular mass of 49 kDa that exists as a hexamer with a native molecular mass of 300 kDa. A ring-shaped hexameric form was revealed by electron microscopic and image processing analyses. NOXtp catalyzed the oxidization of NADH and NADPH and predominantly converted O(2) to H(2)O, but not to H(2)O(2), as in the case of most other NOX enzymes. To our knowledge, this is the first example of a NOX that can produce H(2)O predominantly in a thermophilic organism. As an enzyme with two cysteine residues, NOXtp contains a cysteinyl redox center at Cys45 in addition to FAD. Mutant analysis suggests that Cys45 in NOXtp plays a key role in the four-electron reduction of O(2) to H(2)O, but not in the two-electron reduction of O(2) to H(2)O(2).

Structural and functional characterization of osmotically inducible protein C (OsmC) from Thermococcus kodakaraensis KOD1

Osmotically inducible protein C (OsmC) is involved in the cellular defense mechanism against oxidative stress caused by exposure to hyperoxides or elevated osmolarity. OsmC was identified by two-dimensional electrophoresis (2DE) analysis as a protein that is overexpressed in response to osmotic stress, but not under heat and oxidative stress. Here, an OsmC gene from T. kodakaraensis KOD1 was cloned and expressed in Escherichia coli. TkOsmC showed a homotetrameric structure based on gel filtration and electron microscopic analyses. TkOsmC has a significant peroxidase activity toward both organic and inorganic peroxides in high, but not in low temperature.

Structural and functional conversion of molecular chaperone ClpB from the gram-positive halophilic lactic acid bacterium Tetragenococcus halophilus mediated by ATP and stress

In this study, we report the purification, initial structural characterization, and functional analysis of the molecular chaperone ClpB from the gram-positive, halophilic lactic acid bacterium Tetragenococcus halophilus. A recombinant T. halophilus ClpB (ClpB(Tha)) was overexpressed in Escherichia coli and purified by affinity chromatography, hydroxyapatite chromatography, and gel filtration chromatography. As demonstrated by gel filtration chromatography, chemical cross-linking with glutaraldehyde, and electron microscopy, ClpB(Tha) forms a homohexameric single-ring structure in the presence of ATP under nonstress conditions. However, under stress conditions, such as high-temperature (>45 degrees C) and high-salt concentrations (>1 M KCl), it dissociated into dimers and monomers, regardless of the presence of ATP. The hexameric ClpB(Tha) reactivated heat-aggregated proteins dependent upon the DnaK system from T. halophilus (KJE(Tha)) and ATP. Interestingly, the mixture of dimer and monomer ClpB(Tha), which was formed under stress conditions, protected substrate proteins from thermal inactivation and aggregation in a manner similar to those of general molecular chaperones. From these results, we hypothesize that ClpB(Tha) forms dimers and monomers to function as a holding chaperone under stress conditions, whereas it forms a hexamer ring to function as a disaggregating chaperone in cooperation with KJE(Tha) and ATP under poststress conditions.

The maize Oil yellow1 (Oy1) gene encodes the I subunit of magnesium chelatase

Semi-dominant Oil yellow1 (Oy1) mutants of maize (Zea mays) are deficient in the conversion of protoporphyrin IX to magnesium protoporphyrin IX, the first committed step of chlorophyll biosynthesis. Using a candidate gene approach, a cDNA clone was isolated that was predicted to encode the I subunit of magnesium chelatase (ZmCHLI) and mapped to the same genetic interval as Oy1. Allelic variation was identified at ZmCHLI between wild-type plants and plants carrying semi-dominant alleles of Oy1. These differences revealed putative amino acid substitutions that could account for the alterations in protein function. Candidate lesions were tested by introduction of homologous changes into the Synechocystis magnesium chelatase I gene (SschlI) and characterization of the activity of mutant protein variants in an in vitro enzyme activity assay. The results of these analyses suggest that SsChlI protein variants containing the substitutions identified in the dominant Oy1 maize alleles lack activity necessary for magnesium chelation and confer a semi-dominant phenotype via competitive inhibition of wild-type SsChlI.

Interactions within the ClpB/DnaK bi-chaperone system from Escherichia coli

ClpB and DnaK form a bi-chaperone system that reactivates strongly aggregated proteins in vivo and in vitro. Previously observed interaction between purified ClpB and DnaK suggested that one of the chaperones might recruit its partner during substrate reactivation. We show that ClpB from Escherichia coli binds at the substrate binding site of DnaK and the interaction is supported by the N-terminal domain and the middle domain of ClpB. Moreover, the interaction between ClpB and DnaK depends on the nucleotide-state of DnaK: it is stimulated by ADP and inhibited by ATP. These observations indicate that DnaK recognizes selected structural motifs in ClpB as "pseudo-substrates" and that ClpB may compete with bona fide substrates of DnaK. We conclude that direct interaction between ClpB and DnaK does not mediate a substrate transfer between the chaperones, it may, however, play a role in the recruitment of the bi-chaperone system to specific recognition sites in aggregated particles.

Coordinated synthesis of the two ClpB isoforms improves the ability of Escherichia coli to survive thermal stress

Eubacteria synthesize a full-length (ClpB95) and a N-terminally truncated (ClpB80) version of the ClpB disaggregase owing to the presence of a translation initiation site within the clpB transcript. Why these two isoforms have been evolutionary conserved is poorly understood. Here, we constructed a series of E. coli strains and plasmids allowing production of the ClpB95/ClpB80 pair, ClpB95 alone, or ClpB80 alone from near physiological concentrations to a 6-10-fold excess over normal cellular levels. We found that although overexpressed ClpB95 or ClpB80 can independently restore basal thermotolerance to DeltaclpB cells, strains expressing ClpB80 from the clpB chromosomal locus do not exhibit increased resistance to thermal killing at 50 degrees C relative to clpB null cells. Furthermore, synthesis of physiological levels of ClpB95 is less effective than coordinated expression of ClpB95/ClpB80 in protecting E. coli from thermal killing. These results provide an explanation for the conservation of the two ClpB isoforms in eubacteria and are consistent with the fact that wild type E. coli maintains the ClpB80 to ClpB95 ratio at a nearly constant value of 0.4-0.5 under a variety of stress conditions.

The N-terminal domain ofEscherichia coliClpB enhances chaperone function

ClpB/Hsp104 collaborates with the Hsp70 system to promote the solubilization and reactivation of proteins that misfold and aggregate following heat shock. In Escherichia coli and other eubacteria, two ClpB isoforms (ClpB95 and ClpB80) that differ by the presence or absence of a highly mobile 149-residues long N-terminus domain are synthesized from the same transcript. Whether and how the N-domain contributes to ClpB chaperone activity remains controversial. Here, we show that, whereas fusion of a 20-residues long hexahistidine extension to the N-terminus of ClpB95 interferes with its in vivo and in vitro activity, the same tag has no detectable effect on ClpB80 function. In addition, ClpB95 is more effective than ClpB80 at restoring the folding of the model protein preS2-beta-galactosidase as stress severity increases, and is superior to ClpB80 in improving the high temperature growth and low temperature recovery of dnaK756 DeltaclpB cells. Our results are consistent with a model in which the N-domain of ClpB95 maximizes substrate processing under conditions where the cellular supply of free DnaK-DnaJ is limiting.

Genetic analysis reveals domain interactions of Arabidopsis Hsp100/ClpB and cooperation with the small heat shock protein chaperone system

We have defined amino acids important for function of the Arabidopsis thaliana Hsp100/ClpB chaperone (AtHsp101) in acquired thermotolerance by isolating recessive, loss-of-function mutations and a novel semidominant, gain-of-function allele [hot1-4 (A499T)]. The hot1-4 allele is unusual in that it not only fails to develop thermotolerance to 45 degrees C after acclimation at 38 degrees C, but also is sensitive to 38 degrees C, which is a permissive temperature for wild-type and loss-of-function mutants. hot1-4 lies between nucleotide binding domain 1 (NBD1) and NBD2 in a coiled-coil domain that is characteristic of the Hsp100/ClpB proteins. We then isolated two classes of intragenic suppressor mutations of hot1-4: loss-of-function mutations (Class 1) that eliminated the 38 degrees C sensitivity, but did not restore thermotolerance function to hot1-4, and Class 2 suppressors that restored acquired thermotolerance function to hot1-4. Location of the hot1-4 Class 2 suppressors supports a functional link between the coiled-coil domain and both NBD1 and the axial channel of the Hsp100/ClpB hexamer. In addition, the strongest Class 2 suppressors restored solubility of aggregated small heat shock proteins (sHsps) after heat stress, revealing genetic interaction of the Hsp100/ClpB and sHsp chaperone systems. These results also demonstrate that quantitative phenotypes can be used for in vivo genetic dissection of protein mechanism in Arabidopsis.

Molecular analysis of the Vibrio cholerae type II secretion ATPase EpsE

The type II secretion system is a macromolecular assembly that facilitates the extracellular translocation of folded proteins in gram-negative bacteria. EpsE, a member of this secretion system in Vibrio cholerae, contains a nucleotide-binding motif composed of Walker A and B boxes that are thought to participate in binding and hydrolysis of ATP and displays structural homology to other transport ATPases. Here we demonstrate that purified EpsE is an Mg2+-dependent ATPase and define optimal conditions for the hydrolysis reaction. EpsE displays concentration-dependent activity, which may suggest that the active form is oligomeric. Size exclusion chromatography showed that the majority of purified EpsE is monomeric; however, detailed analyses of specific activities obtained following gel filtration revealed the presence of a small population of active oligomers. We further report that EpsE binds zinc through a tetracysteine motif near its carboxyl terminus, yet metal displacement assays suggest that zinc is not required for catalysis. Previous studies describing interactions between EpsE and other components of the type II secretion pathway together with these data further support the hypothesis that EpsE functions to couple energy to the type II apparatus, thus enabling secretion.

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.

The ClpB/Hsp104 molecular chaperone-a protein disaggregating machine

ClpB and Hsp104 (ClpB/Hsp104) are essential proteins of the heat-shock response and belong to the class 1 family of Clp/Hsp100 AAA+ ATPases. Members of this family form large ring structures and contain two AAA+ modules, which consist of a RecA-like nucleotide-binding domain (NBD) and an alpha-helical domain. Furthermore, ClpB/Hsp104 has a longer middle region, the ClpB/Hsp104-linker, which is essential for chaperone activity. Unlike other Clp/Hsp100 proteins, however, ClpB/Hsp104 neither associates with a cellular protease nor directs the degradation of its substrate proteins. Rather, ClpB/Hsp104 is a bona fide molecular chaperone, which has the remarkable ability to rescue proteins from an aggregated state. The full recovery of these proteins requires the assistance of the cognate DnaK/Hsp70 chaperone system. The mechanism of this "bi-chaperone" network, however, remains elusive. Here we review the current understanding of the structure-function relationship of the ClpB/Hsp104 molecular chaperone and its role in protein disaggregation.

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.

Global transcriptome analysis of the heat shock response of Shewanella oneidensis

Shewanella oneidensis is an important model organism for bioremediation studies because of its diverse respiratory capabilities. However, the genetic basis and regulatory mechanisms underlying the ability of S. oneidensis to survive and adapt to various environmentally relevant stresses is poorly understood. To define this organism's molecular response to elevated growth temperatures, temporal gene expression profiles were examined in cells subjected to heat stress by using whole-genome DNA microarrays for S. oneidensis. Approximately 15% (n = 711) of the total predicted S. oneidensis genes (n = 4,648) represented on the microarray were significantly up- or downregulated (P < 0.05) over a 25-min period after shift to the heat shock temperature. As expected, the majority of the genes that showed homology to known chaperones and heat shock proteins in other organisms were highly induced. In addition, a number of predicted genes, including those encoding enzymes in glycolysis and the pentose cycle, serine proteases, transcriptional regulators (MerR, LysR, and TetR families), histidine kinases, and hypothetical proteins were induced. Genes encoding membrane proteins were differentially expressed, suggesting that cells possibly alter their membrane composition or structure in response to variations in growth temperature. A substantial number of the genes encoding ribosomal proteins displayed downregulated coexpression patterns in response to heat stress, as did genes encoding prophage and flagellar proteins. Finally, a putative regulatory site with high conservation to the Escherichia coli sigma32-binding consensus sequence was identified upstream of a number of heat-inducible genes.

Nucleotide-induced switch in oligomerization of the AAA+ ATPase ClpB

ClpB is a member of the bacterial protein-disaggregating chaperone machinery and belongs to the AAA(+) superfamily of ATPases associated with various cellular activities. The mechanism of ClpB-assisted reactivation of strongly aggregated proteins is unknown and the oligomeric state of ClpB has been under discussion. Sedimentation equilibrium and sedimentation velocity show that, under physiological ionic strength in the absence of nucleotides, ClpB from Escherichia coli undergoes reversible self-association that involves protein concentration-dependent populations of monomers, heptamers, and intermediate-size oligomers. Under low ionic strength conditions, a heptamer becomes the predominant form of ClpB. In contrast, ATP gamma S, a nonhydrolyzable ATP analog, as well as ADP stabilize hexameric ClpB. Consistently, electron microscopy reveals that ring-type oligomers of ClpB in the absence of nucleotides are larger than those in the presence of ATP gamma S. Thus, the binding of nucleotides without hydrolysis of ATP produces a significant change in the self-association equilibria of ClpB: from reactions supporting formation of a heptamer to those supporting a hexamer. Our results show how ClpB and possibly other related AAA(+) proteins can translate nucleotide binding into a major structural transformation and help explain why previously published electron micrographs of some AAA(+) ATPases detected both six- and sevenfold particle symmetry.

Structure and function of the middle domain of ClpB from Escherichia coli

ClpB belongs to the Hsp100/Clp ATPase family. Whereas a homologue of ClpB, ClpA, interacts with and stimulates the peptidase ClpP, ClpB does not associate with peptidases and instead cooperates with DnaK/DnaJ/GrpE in an efficient reactivation of severely aggregated proteins. The major difference between ClpA and ClpB is located in the middle sequence region (MD) that is much longer in ClpB than in ClpA and contains several segments of coiled-coil-like heptad repeats. The function of MD is unknown. We purified the isolated MD fragment of ClpB from Escherichia coli (residues 410-570). Circular dichroism (CD) detected a high population of alpha-helical structure in MD. Temperature-induced changes in CD showed that MD is a thermodynamically stable folding domain. Sedimentation equilibrium showed that MD is monomeric in solution. We produced four truncated variants of ClpB with deletions of the following heptad-repeat-containing regions in MD: 417-455, 456-498, 496-530, and 531-569. We found that the removal of each heptad-repeat region within MD strongly inhibited the oligomerization of ClpB, which produced low ATPase activity of the truncated ClpB variants as well as their low chaperone activity in vivo. Only one ClpB variant (Delta417-455) could partially complement the growth defect of the clpB-null E. coli strain at 50 degrees C. Our results show that heptad repeats in MD play an important role in stabilization of the active oligomeric form of ClpB. The heptad repeats are likely involved in stabilization of an intra-MD helical bundle rather than an intersubunit coiled coil.

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.

Identification and mapping of self-assembling protein domains encoded by the Escherichia coli K-12 genome by use of lambda repressor fusions

Self-assembling proteins and protein fragments encoded by the Escherichia coli genome were identified from E. coli K-12 strain MG1655. Libraries of random DNA fragments cloned into a series of lambda repressor fusion vectors were subjected to selection for immunity to infection by phage lambda. Survivors were identified by sequencing the ends of the inserts, and the fused protein sequence was inferred from the known genomic sequence. Four hundred sixty-three nonredundant open reading frame-encoded interacting sequence tags (ISTs) were recovered from sequencing 2,089 candidates. These ISTs, which range from 16 to 794 amino acids in length, were clustered into families of overlapping fragments, identifying potential homotypic interactions encoded by 232 E. coli genes. Repressor fusions identified ISTs from genes in every protein-based functional category, but membrane proteins were underrepresented. The IST-containing genes were enriched for regulatory proteins and for proteins that form higher-order oligomers. Forty-eight (20.7%) homotypic proteins identified by ISTs are predicted to contain coiled coils. Although most of the IST-containing genes are identifiably related to proteins in other bacterial genomes, more than half of the ISTs do not have identifiable homologs in the Protein Data Bank, suggesting that they may include many novel structures. The data are available online at http://oligomers.tamu.edu/.

Protein Binding and Disruption by Clp/Hsp100 Chaperones

Clp/Hsp100 chaperones work with other cellular chaperones and proteases to control the quality and amounts of many intracellular proteins. They employ an ATP-dependent protein unfoldase activity to solubilize protein aggregates or to target specific classes of proteins for degradation. The structural complexity of Clp/Hsp100 proteins combined with the complexity of the interactions with their macromolecular substrates presents a considerable challenge to understanding the mechanisms by which they recognize and unfold substrates and deliver them to downstream enzymes. Fortunately, high-resolution structural data is now available for several of the chaperones and their functional partners, which together with mutational data on the chaperones and their substrates has provided a glimmer of light at the end of the Clp/Hsp100 tunnel.

Regulation of the transcriptional activator NtrC1: structural studies of the regulatory and AAA+ ATPase domains

Transcription by sigma54 RNA polymerase depends on activators that contain ATPase domains of the AAA+ class. These activators, which are often response regulators of two-component signal transduction systems, remodel the polymerase so that it can form open complexes at promoters. Here, we report the first crystal structures of the ATPase domain of an activator, the NtrC1 protein from the extreme thermophile Aquifex aeolicus. This domain alone, which is active, crystallized as a ring-shaped heptamer. The protein carrying both the ATPase and adjacent receiver domains, which is inactive, crystallized as a dimer. In the inactive dimer, one residue needed for catalysis is far from the active site, and extensive contacts among the domains prevent oligomerization of the ATPase domain. Oligomerization, which completes the active site, depends on surfaces that are buried in the dimer, and hence, on a rearrangement of the receiver domains upon phosphorylation. A motif in the ATPase domain known to be critical for coupling energy to remodeling of polymerase forms a novel loop that projects from the middle of an alpha helix. The extended, structured loops from the subunits of the heptamer localize to a pore in the center of the ring and form a surface that could contact sigma54.

The Structure of ClpB

Molecular chaperones assist protein folding by facilitating their "forward" folding and preventing aggregation. However, once aggregates have formed, these chaperones cannot facilitate protein disaggregation. Bacterial ClpB and its eukaryotic homolog Hsp104 are essential proteins of the heat-shock response, which have the remarkable capacity to rescue stress-damaged proteins from an aggregated state. We have determined the structure of Thermus thermophilus ClpB (TClpB) using a combination of X-ray crystallography and cryo-electron microscopy (cryo-EM). Our single-particle reconstruction shows that TClpB forms a two-tiered hexameric ring. The ClpB/Hsp104-linker consists of an 85 A long and mobile coiled coil that is located on the outside of the hexamer. Our mutagenesis and biochemical data show that both the relative position and motion of this coiled coil are critical for chaperone function. Taken together, we propose a mechanism by which an ATP-driven conformational change is coupled to a large coiled-coil motion, which is indispensable for protein disaggregation.

Importance of low-oligomeric-weight species for prion propagation in the yeast prion system Sup35/Hsp104

The [PSI+] determinant of Saccharomyces cerevisiae, consisting of the cytosolic translation termination factor Sup35, is a prion-type genetic element that induces an inheritable conformational change and converts the Sup35 protein into amyloid fibers. The molecular chaperone Hsp104 is required to maintain self-replication of [PSI+]. We observe in vitro that addition of catalytic amounts of Hsp104 to the prion-determining region of the NM domain of Sup35, Sup355-26, results in the dissociation of oligomeric Sup35 into monomeric species. Several intermediates of Sup355-26 could be detected during this process. Strong interactions are found between Hsp104 and hexameric/tetrameric Sup355-26, whereas the intermediate and monomeric "release" forms show a decreased affinity with respect to Hsp104, as monitored by saturation transfer difference and diffusion-ordered NMR spectroscopic experiments. Interactions are mediated mostly by the side chains of Gln, Asn, and Tyr residues in Sup355-26. No interaction can be detected between Hsp104 and higher oligomeric states (>/=8) of Sup355-26. Taking into account the fact that Hsp104 is required for maintenance of [PSI+], we suggest that low-oligomeric-weight species of Sup35 are important for prion propagation in yeast.

Molecular architecture of the ATP-dependent CodWX protease having an N-terminal serine active site

CodWX in Bacillus subtilis is an ATP-dependent, N-terminal serine protease, consisting of CodW peptidase and CodX ATPase. Here we show that CodWX is an alkaline protease and has a distinct molecular architecture. ATP hydrolysis is required for the formation of the CodWX complex and thus for its proteolytic function. Remarkably, CodX has a 'spool-like' structure that is formed by interaction of the intermediate domains of two hexameric or heptameric rings. In the CodWX complex, CodW consisting of two stacked hexameric rings (WW) binds to either or both ends of a CodX double ring (XX), forming asymmetric (WWXX) or symmetric cylindrical particles (WWXXWW). CodWX can also form an elongated particle, in which an additional CodX double ring is bound to the symmetric particle (WWXXWWXX). In addition, CodWX is capable of degrading EzrA, an inhibitor of FtsZ ring formation, implicating it in the regulation of cell division. Thus, CodWX appears to constitute a new type of protease that is distinct from other ATP-dependent proteases in its structure and proteolytic mechanism.

Roles of individual domains and conserved motifs of the AAA+ chaperone ClpB in oligomerization, ATP hydrolysis, and chaperone activity

ClpB of Escherichia coli is an ATP-dependent ring-forming chaperone that mediates the resolubilization of aggregated proteins in cooperation with the DnaK chaperone system. ClpB belongs to the Hsp100/Clp subfamily of AAA+ proteins and is composed of an N-terminal domain and two AAA-domains that are separated by a "linker" region. Here we present a detailed structure-function analysis of ClpB, dissecting the individual roles of ClpB domains and conserved motifs in oligomerization, ATP hydrolysis, and chaperone activity. Our results show that ClpB oligomerization is strictly dependent on the presence of the C-terminal domain of the second AAA-domain, while ATP binding to the first AAA-domains stabilized the ClpB oligomer. Analysis of mutants of conserved residues in Walker A and B and sensor 2 motifs revealed that both AAA-domains contribute to the basal ATPase activity of ClpB and communicate in a complex manner. Chaperone activity strictly depends on ClpB oligomerization and the presence of a residual ATPase activity. The N-domain is dispensable for oligomerization and for the disaggregating activity in vitro and in vivo. In contrast the presence of the linker region, although not involved in oligomerization, is essential for ClpB chaperone activity.