The allosteric transition in DnaK probed by infrared difference spectroscopy. Concerted ATP-induced rearrangement of the substrate binding domain

The biological activity of DnaK, the bacterial representative of the Hsp70 protein family, is regulated by the allosteric interaction between its nucleotide and peptide substrate binding domains. Despite the importance of the nucleotide-induced cycling of DnaK between substrate-accepting and releasing states, the heterotropic allosteric mechanism remains as yet undefined. To further characterize this mechanism, the nucleotide-induced absorbance changes in the vibrational spectrum of wild-type DnaK was characterized. To assign the conformation sensitive absorption bands, two deletion mutants (one lacking the C-terminal alpha-helical subdomain and another comprising only the N-terminal ATPase domain), and a single-point DnaK mutant (T199A) with strongly reduced ATPase activity, were investigated by time-resolved infrared difference spectroscopy combined with the use of caged-nucleotides. The results indicate that (1) ATP, but not ADP, binding promotes a conformational change in both subdomains of the peptide binding domain that can be individually resolved; (2) these conformational changes are kinetically coupled, most likely to ensure a decrease in the affinity of DnaK for peptide substrates and a concomitant displacement of the lid away from the peptide binding site that would promote efficient diffusion of the released peptide to the medium; and (3) the alpha-helical subdomain contributes to stabilize the interdomain interface against the thermal challenge and allows bidirectional transmission of the allosteric signal between the ATPase and substrate binding domains at stress temperatures (42 degrees C).     

Scanning mutagenesis identifies amino acid residues essential for the in vivo activity of the Escherichia coli DnaJ (Hsp40) J-domain

The DnaJ (Hsp40) cochaperone regulates the DnaK (Hsp70) chaperone by accelerating ATP hydrolysis in a cycle closely linked to substrate binding and release. The J-domain, the signature motif of the Hsp40 family, orchestrates interaction with the DnaK ATPase domain. We studied the J-domain by creating 42 mutant E. coli DnaJ variants and examining their phenotypes in various separate in vivo assays, namely, bacterial growth at low and high temperatures, motility, and propagation of bacteriophage lambda. Most mutants studied behaved like wild type in all assays. In addition to the (33)HisProAsp(35) (HPD) tripeptide found in all known functional J-domains, our study uncovered three new single substitution mutations (Y25A, K26A, and F47A) that totally abolish J-domain function. Furthermore, two glycine substitution mutants in an exposed flexible loop (R36G, N37G) showed partial loss of J-domain function alone and complete loss of function as a triple (RNQ-GGG) mutant coupled with the phenotypically silent Q38G. Interestingly, all the essential residues map to a small region on the same solvent-exposed face of the J-domain. Engineered mutations in the corresponding residues of the human Hdj1 J-domain grafted in E. coli DnaJ also resulted in loss of function, suggesting an evolutionarily conserved interaction surface. We propose that these clustered residues impart critical sequence determinants necessary for J-domain catalytic activity and reversible contact interface with the DnaK ATPase domain.     

ATPase-defective derivatives of Escherichia coli DnaK that behave differently with respect to ATP-induced conformational change and peptide release.

We have characterized the effects of the T199S, T199A, and K70A mutations on the biochemical activity and in vivo functioning of Escherichia coli DnaK. Threonine-199 is the site of autophosphorylation of DnaK, and the lysine residue of bovine Hsc70 corresponding to K70 of DnaK has been shown to be essential for the hydrolysis of ATP. The dnaK alleles T199A and K70A are completely unable, and the T199S allele is only partially able, to complement the defects of a DeltadnaK mutant. The ATPase activities of the DnaK T199A and DnaK K70A proteins are nearly abolished, while the ATPase activity of the DnaK T199S protein has a steady-state rate similar to that of wild-type DnaK. The DnaK T199S protein also retains approximately 13% of the autophosphorylation activity of wild-type DnaK, while the autophosphorylation activities of the T199A and K70A derivatives are completely abolished. All four DnaK proteins bind a model peptide substrate, and the wild-type, T199A, and T199S DnaK proteins release the peptide with similar kinetics upon the addition of ATP. The DnaK K70A protein, in contrast, does not release the peptide upon the addition of ATP. ATP induces a conformational change in the wild-type, T199A, and T199S DnaK proteins but not in the DnaK K70A protein. The T199A and K70A mutations both disrupt the ATPase activity of DnaK but have profoundly different effects on the ATP-induced conformational change and peptide release activities of DnaK, implying that the two mutations affect different steps in the functional cycle of DnaK. The DnaK T199S protein represents a new class of DnaK mutant, one which has near-normal levels of ATPase activity and undergoes an ATP-induced conformational change that results in the release of peptide but which is not able to fully complement loss of DnaK function in the cell.     

Interdomain interaction through helices A and B of DnaK peptide binding domain

In order to better define the structural elements involved in allosteric signalling, wild-type DnaK and three deletion mutants of the peptide binding domain have been characterized by biophysical (steady-state and time-resolved fluorescence) and biochemical methods. In the presence of ATP the chemical environment of the single tryptophan residue of DnaK, located in the ATPase domain, becomes less polar, as seen by a blue shift of the emission maximum and a shortening of the fluorescence lifetime, and its accessibility to polar quenchers is drastically reduced. These nucleotide-dependent modifications are also observed for the deletion mutant DnaK1-537, but not for DnaK1-507 or DnaK1-385, and thus rely on the presence of residues 507–537 (helices A and the N-terminal half of B) of the peptide binding domain. These data indicate that αA and half αB contribute to the allosteric communication of DnaK. In the presence of ATP, they promote a conformational change that displaces a residue(s) of the peptide binding domain towards a region of the ATPase domain where the tryptophan residue (W102) is located. A putative role for these helical segments as regulators of the position of the lid is discussed.     

Functional defects of the DnaK756 mutant chaperone of Escherichia coli indicate distinct roles for amino- and carboxyl-terminal residues in substrate and co-chaperone interaction and interdomain communication

The first discovery of an Hsp70 chaperone gene was the isolation of an Escherichia coli mutant, dnaK756, which rendered the cells resistant to lytic infection with bacteriophage lambda. The DnaK756 mutant protein has since been used to establish many of the cellular roles and biochemical properties of DnaK. DnaK756 has three glycine-to-aspartate substitutions at residues 32, 455, and 468, which were reported to result in defects in intrinsic and GrpE-stimulated ATPase activities, substrate binding, stability of the substrate-binding domain, interdomain communication, and, consequently, defects in chaperone activity. To dissect the effects of the different amino acid substitutions in DnaK756, we analyzed two DnaK variants carrying only the amino-terminal (residue 32) or the two carboxyl-terminal (residues 455 and 468) substitutions. The amino-terminal substitution interfered with the GrpE-stimulated ATPase activity. The carboxyl-terminal mutations (i) affected stability and function of the substrate-binding domain, (ii) caused a 10-fold elevated ATP hydrolysis rate, but (iii) did not severely affect domain coupling. Surprisingly, DnaK chaperone activity was more severely compromised by the amino-terminal than by the carboxyl-terminal amino acid substitutions both in vivo and in vitro. In the in vitro refolding of denatured firefly luciferase, the defect of the DnaK variant carrying the amino-terminal substitution results from its inability to release, upon GrpE-mediated nucleotide exchange, bound luciferase in a folding competent state. Our results indicate that the DnaK-DnaJ-GrpE chaperone system can tolerate suboptimal substrate binding, whereas the tight kinetic control of substrate dissociation by GrpE is essential.     

A GrpE mutant containing the NH(2)-terminal "tail" region is able to displace bound polypeptide substrate from DnaK

A key feature to the dimeric structure for the GrpE heat shock protein is the pair of long helices at the NH(2)-terminal end followed by a presumable extended segment of about 30 amino acids from each monomer. We have constructed a GrpE deletion mutant protein that contains only the unique tail portion (GrpE1-89) and another that is missing this region (GrpE88-197). Circular dichroism analysis shows that the GrpE1-89 mutant still contains one-third percent alpha-helical secondary structure. Using an assay that measures bound peptide to DnaK we show that the GrpE1-89 is able to lower the amount of bound peptide, whereas GrpE88-197 has no effect. Additionally, when the same peptide binding assay is carried out with the COOH-terminal domain of DnaK, the full-length GrpE and the two GrpE deletion mutants show little to no effect on peptide release. Furthermore, the GrpE88-197 mutant is able to enhance the off-rate of nucleotide from DnaK and the 1-89 mutant has no effect on the nucleotide release. Similar results of nucleotide release are observed with the NH(2)-terminal ATPase domain mutant of DnaK. The results presented show directly that there is interaction between the GrpE protein's "tail" region and the substrate COOH-terminal peptide binding domain of DnaK, although the effect is only fully manifest with an intact full-length DnaK molecule.     

The chaperone function of DnaK requires the coupling of ATPase activity with substrate binding through residue E171.

Central to the chaperone function of Hsp70 stress proteins including Escherichia coli DnaK is the ability of Hsp70 to bind unfolded protein substrates in an ATP-dependent manner. Mg2+/ATP dissociates bound substrates and, furthermore, substrate binding stimulates the ATPase of Hsp70. This coupling is proposed to require a glutamate residue, E175 of bovine Hsc70, that is entirely conserved within the Hsp70 family, as it contacts bound Mg2+/ATP and is part of a hinge required for a postulated ATP-dependent opening/closing movement of the nucleotide binding cleft which then triggers substrate release. We analyzed the effects of dnaK mutations which alter the corresponding glutamate-171 of DnaK to alanine, leucine or lysine. In vivo, the mutated dnaK alleles failed to complement the delta dnaK52 mutation and were dominant negative in dnaK+ cells. In vitro, all three mutant DnaK proteins were inactive in known DnaK-dependent reactions, including refolding of denatured luciferase and initiation of lambda DNA replication. The mutant proteins retained ATPase activity, as well as the capacity to bind peptide substrates. The intrinsic ATPase activities of the mutant proteins, however, did exhibit increased Km and Vmax values. More importantly, these mutant proteins showed no stimulation of ATPase activity by substrates and no substrate dissociation by Mg2+/ATP. Thus, glutamate-171 is required for coupling of ATPase activity with substrate binding, and this coupling is essential for the chaperone function of DnaK.     

The J-domain of Hsp40 couples ATP hydrolysis to substrate capture in Hsp70

The Escherichia coli Hsp40 DnaJ uses its J-domain to target substrate polypeptides for binding to the Hsp70 DnaK, but the mechanism of J-domain function has been obscured by a substrate-like interaction between DnaJ and DnaK. ATP hydrolysis in DnaK is associated with a conformational change that captures the substrate, and both DnaJ and substrate can stimulate ATP hydrolysis. However, substrates cannot trigger capture by DnaK in the presence of ATP, and substrates stimulate a DnaK conformational change that is uncoupled from ATP hydrolysis. The role of the J-domain was examined using the fluorescent derivative of a fusion protein composed of the J-domain and a DnaK-binding peptide. In the absence of ATP, DnaK-binding affinity of the fusion protein is similar to that of the unfused peptide. However, in the presence of ATP, the affinity of the fusion protein is dramatically increased, which is opposite to the decrease in DnaK affinity typically exhibited by peptides. Binding of a fusion protein that contains a defective J-domain is insensitive to ATP. According to results from isothermal titration calorimetry, the J-domain binds to the DnaK ATPase domain with weak affinity (K(D) = 23 microM at 20 degrees C). The interaction is characterized by a positive enthalpy, small heat capacity change (DeltaC(p)= -33 kcal mol(-1)), and increasing binding affinity for increasing temperatures in the physiological range. In conditions that support binding of the J-domain to the ATPase domain, the J-domain accelerates ATP hydrolysis and a simultaneous conformational change in DnaK that is associated with peptide capture. The defective J-domain is inactive, despite the fact that it binds to the DnaK ATPase domain with higher than wild-type affinity. The results are most consistent with an allosteric mechanism of J-domain action in which the J-domain couples ATP hydrolysis to peptide capture by accelerating ATP hydrolysis and delaying DnaK closure until ATP is hydrolyzed.     

Structure-function analysis of the Escherichia coli GrpE heat shock protein.

We have isolated various missense mutations in the essential grpE gene of Escherichia coli based on the inability to propagate bacteriophage lambda. To better understand the biochemical mechanisms of GrpE action in various biological processes, six mutant proteins were overexpressed and purified. All of them, GrpE103, GrpE66, GrpE2/280, GrpE17, GrpE13a and GrpE25, have single amino acid substitutions located in highly conserved regions throughout the GrpE sequence. The biochemical defects of each mutant GrpE protein were identified by examining their abilities to: (i) support in vitro lambda DNA replication; (ii) stimulate the weak ATPase activity of DnaK; (iii) dimerize and oligomerize, as judged by glutaraldehyde crosslinking and HPLC size chromatography; (iv) interact with wild-type DnaK protein using either an ELISA assay, glutaraldehyde crosslinking or HPLC size chromatography. Our results suggest that GrpE can exist in a dimeric or oligomeric form, depending on its relative concentration, and that it dimerizes/oligomerizes through its N-terminal region, most likely through a computer predicted coiled-coil region. Analysis of several mutant GrpE proteins indicates that an oligomer of GrpE is the most active form that interacts stably with DnaK and that the interaction is vital for GrpE biological function. Our results also demonstrate that both the N-terminal and C-terminal regions are important for GrpE function in lambda DNA replication and its co-chaperone activity with DnaK.     

Structure and energetics of an allele-specific genetic interaction between dnaJ and dnaK: correlation of nuclear magnetic resonance chemical shift perturbations in the J-domain of Hsp40/DnaJ with binding affinity for the ATPase domain of Hsp70/DnaK

The molecular chaperone machine composed of Escherichia coli Hsp70/DnaK and Hsp40/DnaJ binds and releases client proteins in cycles of ATP-dependent protein folding, membrane translocation, disassembly, and degradation. The J-domain of DnaJ simultaneously stimulates ATP hydrolysis in the ATPase domain and capture of the client protein in the peptide-binding domain of DnaK. ATP-dependent binding of DnaJ to DnaK mimics DnaJ-dependent capture of a client protein. The dnaJ mutation that replaces aspartate-35 with asparagine (D35N) in the J-domain causes a defect in binding of DnaJ to DnaK. The dnaK mutation that replaces arginine-167 with alanine (R167A) in the ATPase domain of DnaK(R167A) restores binding of DnaJ(D35N). This genetic interaction was said to be allele-specific because wild-type DnaJ does not bind to DnaK(R167A). The J-domain of DnaJ binds to the ATPase domain of DnaK in its capacity as modulator of DnaK ATPase activity and conformational behavior. Surprisingly, the mutations affect the domainwise interaction in an almost opposite manner. D35N increases the affinity of the J-domain for the ATPase domain. R167A has no affect on the affinity of the ATPase domain for the D35N mutant J-domain, but it reduces the affinity for the wild-type J-domain. Previous amide ((1)H, (15)N) NMR chemical shift perturbation mapping in the J-domain suggested that the ATPase domain binds to J-domain helix II and the flanking loops. In the D35N mutant J-domain, chemical shift perturbations include additional effects at amides in the flexible loop II-III and helix III, which have been proposed to undergo an induced fit conformational change upon binding to DnaK. The integrated magnitudes of chemical shift perturbations for the various J-domain and ATPase domain pairs correlate with the free energies of binding. Thus, the J-domain structure can be described as a dynamic ensemble of conformations that is constrained by binding to the ATPase domain. J-domain helix II bends upon binding to the ATPase domain. D35N increases helix II bending, but less so in combination with R167A in the ATPase domain. Taken together, the results suggest that D35N overstabilizes an induced fit conformational change in loop II-III and helix III that is necessary for the J-domain to couple ATP hydrolysis with a conformational change in DnaK, and R167A destabilizes the induced conformation. Conclusions from this work have implications for understanding mechanisms of protein-protein interaction that are involved in allosteric regulation and genetic suppression.     

Ionic contacts at DnaK substrate binding domain involved in the allosteric regulation of lid dynamics

To gain further insight into the interactions involved in the allosteric transition of DnaK we have characterized wild-type (wt) protein and three mutants in which ionic interactions at the interface between the two subdomains of the substrate binding domain, and within the lid subdomain have been disrupted. Our data show that ionic contacts, most likely forming an electrically charged network, between the N-terminal region of helix B and an inner loop of the beta-sandwich are involved in maintaining the position of the lid relative to the beta-subdomain in the ADP state but not in the ATP state of the protein. Disruption of the ionic interactions between the C-terminal region of helix B and the outer loops of the beta-sandwich, known as the latch, does not have the same conformational consequences but results equally in an inactive protein. This indicates that a variety of mechanisms can inactivate this complex allosteric machine. Our results identify the ionic contacts at the subdomain and interdomain interfaces that are part of the hinge region involved in the ATP-induced allosteric displacement of the lid away from the peptide binding site. These interactions also stabilize peptide-Hsp70 complexes at physiological (37 degrees C) and stress (42 degrees C) temperatures, a requirement for productive substrate (re)folding.     

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

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

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

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

C-terminal domain mutations in ClpX uncouple substrate binding from an engagement step required for unfolding

ClpX mediates ATP-dependent denaturation of specific target proteins and disassembly of protein complexes. Like other AAA + family members, ClpX contains an alphabeta ATPase domain and an alpha-helical C-terminal domain. ClpX proteins with mutations in the C-terminal domain were constructed and screened for disassembly activity in vivo. Seven mutant enzymes with defective phenotypes were purified and characterized. Three of these proteins (L381K, D382K and Y385A) had low activity in disassembly or unfolding assays in vitro. In contrast to wild-type ClpX, substrate binding to these mutants inhibited ATP hydrolysis instead of increasing it. These mutants appear to be defective in a reaction step that engages bound substrate proteins and is required both for enhancement of ATP hydrolysis and for unfolding/disassembly. Some of these side chains form part of the interface between the C-terminal domain of one ClpX subunit and the ATPase domain of an adjacent subunit in the hexamer and appear to be required for communication between adjacent nucleotide binding sites.     

Hsp70 chaperone ligands control domain association via an allosteric mechanism mediated by the interdomain linker

Hsp70 chaperones assist in protein folding, disaggregation, and membrane translocation by binding to substrate proteins with an ATP-regulated affinity that relies on allosteric coupling between ATP-binding and substrate-binding domains. We have studied single- and two-domain versions of the E. coli Hsp70, DnaK, to explore the mechanism of interdomain communication. We show that the interdomain linker controls ATPase activity by binding to a hydrophobic cleft between subdomains IA and IIA. Furthermore, the domains of DnaK dock only when ATP binds and behave independently when ADP is bound. Major conformational changes in both domains accompany ATP-induced docking: of particular importance, some regions of the substrate-binding domain are stabilized, while those near the substrate-binding site become destabilized. Thus, the energy of ATP binding is used to form a stable interface between the nucleotide- and substrate-binding domains, which results in destabilization of regions of the latter domain and consequent weaker substrate binding.     

Structural insights into substrate binding by the molecular chaperone DnaK

How substrate affinity is modulated by nucleotide binding remains a fundamental, unanswered question in the study of 70 kDa heat shock protein (Hsp70) molecular chaperones. We find here that the Escherichia coli Hsp70, DnaK, lacking the entire alpha-helical domain, DnaK(1-507), retains the ability to support lambda phage replication in vivo and to pass information from the nucleotide binding domain to the substrate binding domain, and vice versa, in vitro. We determined the NMR solution structure of the corresponding substrate binding domain, DnaK(393-507), without substrate, and assessed the impact of substrate binding. Without bound substrate, loop L3,4 and strand beta3 are in significantly different conformations than observed in previous structures of the bound DnaK substrate binding domain, leading to occlusion of the substrate binding site. Upon substrate binding, the beta-domain shifts towards the structure seen in earlier X-ray and NMR structures. Taken together, our results suggest that conformational changes in the beta-domain itself contribute to the mechanism by which nucleotide binding modulates substrate binding affinity.     

Detection of a concerted conformational change in the ATPase domain of DnaK triggered by peptide binding

The molecular chaperone DnaK is composed of two functional domains, the ATPase domain and the substrate-binding domain. In this report, we show that peptide binding to DnaK can be sensed in real time through a labeled nucleotide bound in the ATPase domain. Specifically, when N8-(4-N'-methylanthraniloylaminobutyl)-8-aminoadenosine 5'-triphosphate (MABA)-ATP.DnaK complexes are rapidly mixed with excess peptide, MABA fluorescence rapidly increases and the rate of increase is proportional to peptide concentration. Analysis of the formation traces yield on and off rate constants that are exactly equal to the rate constants obtained from experiments that directly probe peptide binding to DnaK. These results are the first to show that peptide binding to ATP.DnaK triggers a concerted conformational change in the ATPase domain.     

Importance of the D and E helices of the molecular chaperone DnaK for ATP binding and substrate release

The C-terminal domain of the molecular chaperone DnaK is a compact lid-like structure made up of five alpha-helices (alphaA-alphaE) (residues 508-608) that is followed by a 30-residue disordered, flexible region (609-638). The lid encapsulates the peptide molecule bound in the substrate-binding domain, whereas the function of the 30-residue disordered region is not known. By sequentially deleting the flexible subdomain and the individual lid helices, we deduced the importance of each structural unit to creating long-lived DnaK-peptide complexes. Here we report that (i) the alphaD helix is essential for long-lived DnaK-peptide complexes. For example, ATP triggers the dissociation of a acrylodan-labeled p5 peptide (ap5, a-CLLLSAPRR) from wtDnaK and DnaK595(A-D) with k(off) equal to 7.6 and 8.9 s(-1), respectively, whereas when the D-helix is deleted, creating DnaK578(A-C), k(off) jumps to 207 s(-1). (ii) The presence of the alphaB helix impacts the rate of the ATP-induced high-to-low affinity conformational change. For example, ATP induces this conformational change in a lidless variant, DnaK517(1/2A), with a rate constant of 442 s(-1), whereas, after adding back the B-helix (residues 518-554), ATP induces this conformational change in DnaK554(A-B) with a rate constant of 2.5 s(-1). Our interpretation is that this large decrease occurs because the B-helix of the DnaK554(A-B) is bound in the substrate-binding site. (iii) The deletion analysis also revealed that residues 596-638, which comprise the alphaE helix and the flexible subdomain, affect ATP binding. Our results are consistent with this part of the lid producing conformational heterogeneity, perhaps by binding to the ATPase domain.     

Identification of a region in the N-terminus of Escherichia coli Lon that affects ATPase, substrate translocation and proteolytic activity

Lon, also known as protease La, is an AAA+ protease machine that contains the ATPase and proteolytic domain within each enzyme subunit. Three truncated Escherichia coli Lon (ELon) mutants were generated based on a previous limited tryptic digestion result and hydrogen-deuterium exchange mass spectrometry analyses performed in this study. Using methods developed for characterizing wild-type (WT) Lon, we compared the ATPase, ATP-dependent protein degradation and ATP-dependent peptidase activities. With the exception of not degrading a putative structured substrate known as CcrM (cell-cycle-regulated DNA methyltransferase), the mutant lacking the first 239 residues behaved like WT ELon. Comparing the activity data of WT and ELon mutants reveals that the first 239 residues are not needed for minimal enzyme catalysis. The mutants lacking the first 252 residues or residues 232-252 displayed compromised ATPase, protein degradation and ATP-dependent peptide translocation abilities but retained WT-like steady-state peptidase activity. The binding affinities of WT and Lon mutants were evaluated by determining the concentration of λ N (K(λN)) needed to achieve 50% maximal ATPase stimulation. Comparing the K(λN) values reveals that the region encompassing 232-252 of ELon could contribute to λ N binding, but the effect is modest. Taken together, results generated from this study reveal that the region constituting residues 240-252 of ELon is important for ATPase activity, substrate translocation and protein degradation.     

Contributions of the LPPVK motif of the iron-sulfur template protein IscU to interactions with the Hsc66-Hsc20 chaperone system

Hsc66 (HscA) and Hsc20 (HscB) from Escherichia coli comprise a specialized chaperone system that selectively binds the iron-sulfur cluster template protein IscU. Hsc66 interacts with peptides corresponding to a discrete region of IscU including residues 99-103 (LPPVK), and a peptide containing residues 98-106 stimulates Hsc66 ATPase activity in a manner similar to IscU. To determine the relative contributions of individual residues in the LPPVK motif to Hsc66 binding and regulation, we have carried out an alanine mutagenesis scan of this motif in the Glu98-Cys106 peptide and the IscU protein. Alanine substitutions in the Glu98-Cys106 peptide resulted in decreased ATPase stimulation (2-10-fold) because of reduced binding affinity, with peptide(P101A) eliciting <10% of the parent peptide stimulation. Alanine substitutions in the IscU protein also revealed lower activities resulting from decreased apparent binding affinity, with the greatest changes in Km observed for the Pro101 (77-fold), Val102 (4-fold), and Lys103 (15-fold) mutants. Calorimetric studies of the binding of IscU mutants to the Hsc66.ADP complex showed that the P101A and K103A mutants also exhibit decreased binding affinity for the ADP-bound state. When ATPase stimulatory activity was assayed in the presence of the co-chaperone Hsc20, each of the mutants displayed enhanced binding affinity, but the P101A and V102A mutants exhibited decreased ability to maximally simulate Hsc66 ATPase. A charge mutant containing the motif sequence of NifU, IscU(V102E), did not bind the ATP or ADP states of Hsc66 but did bind Hsc20 and weakly stimulated Hsc66 ATPase in the presence of the co-chaperone. These results indicate that residues in the LPPVK motif are important for IscU interactions with Hsc66 but not for the ability of Hsc20 to target IscU to Hsc66. The results are discussed in the context of a structural model based on the crystallographic structure of the DnaK peptide-binding domain.