Sequence-dependent peptide binding orientation by the molecular chaperone DnaK

Hsp70-class molecular chaperones interact with diverse polypeptide substrates, but there is limited information on the structures of different Hsp70-peptide complexes. We have used a site-directed fluorescence labeling and quenching strategy to investigate the orientation of different peptides bound to DnaK from Escherichia coli. DnaK was selectively labeled on opposite sides of the substrate-binding domain (SBD) with the fluorescent probe bimane, and the ability of peptides containing N- or C-terminal tryptophan residues to quench bimane fluorescence was measured. Tryptophan-labeled derivatives of the model peptide NRLLLTG bound with the same forward orientation previously observed in the crystal structure of the DnaK(SBD)-NRLLLTG complex. Derivatives of this peptide containing arginine in the C-terminal rather than N-terminal region, NTLLLRG, also bound in the forward direction indicating that charged residues in the flanking regions of the peptide are not the major determinant of peptide binding orientation. We also tested peptides having proline in one (ELPLVKI) or two (ELPPVKI) central positions. Tryptophan derivatives of each of these peptides bound with a strong preference for the reverse direction relative to that observed for the NRLLLTG and NTLLLRG peptides. Computer modeling the peptides NRLLLTG and ELPPVKI in both the forward and reverse orientations into the DnaK(SBD) indicated that differential hydrogen-bonding patterns and steric constraints of the central peptide residues are likely causes for differences in their binding orientations. These findings establish that DnaK is able to bind substrates in both forward and reverse orientations and suggest that the central residues of the peptide are the major determinants of directional preference.     

The solution structure of the bacterial HSP70 chaperone protein domain DnaK(393-507) in complex with the peptide NRLLLTG

The Hsp70 family of molecular chaperones participates in a number of cellular processes, including binding to nascent polypeptide chains and assistance in protein (re)folding and degradation. We present the solution structure of the substrate binding domain (residues 393-507) of the Escherichia coli Hsp70, DnaK, that is bound to the peptide NRLLLTG and compare it to the crystal structure of DnaK(389-607) bound to the same peptide. The construct discussed here does not contain the alpha-helical domain that characterizes earlier published peptide-bound structures of the Hsp70s. It is established that removing the alpha-helical domain in its entirety does not affect the primary interactions or structure of the DnaK(393-507) in complex with the peptide NRLLLTG. In particular, the arch that protects the substrate-binding cleft is also formed in the absence of the helical lid. 15N-relaxation measurements show that the peptide-bound form of DnaK(393-507) is relatively rigid. As compared to the peptide-free state, the peptide-bound state of the domain shows distinct, widespread, and contiguous differences in structure extending toward areas previously defined as important to the allosteric regulation of the Hsp70 chaperones.     

Preferential substrate binding orientation by the molecular chaperone HscA

HscA, a specialized bacterial hsp70-class chaperone, interacts with the iron-sulfur cluster assembly protein IscU by recognizing a conserved LPPVK sequence motif at positions 99-103. We have used a site-directed fluorescence labeling and quenching strategy to determine whether HscA binds to IscU in a preferred orientation. HscA was selectively labeled on opposite sides of the substrate binding domain with the fluorescent probe bimane, and the ability of LPPVK-containing peptides having tryptophan at the N or C terminus to quench bimane fluorescence was measured. Quenching was highly dependent on the position of tryptophan in the peptide and the location of bimane on HscA implying a strong directional preference for peptide binding. Similar experiments showed that full-length IscU binds in the same orientation as IscU-derived peptides and that binding orientation is unaffected by the co-chaperone HscB. The preferred orientation of the HscA-IscU complex is the reverse of that previously described for peptide complexes of Escherichia coli DnaK and rat Hsc70 substrate binding domain fragments establishing that hsp70 isoforms can bind peptide/polypeptide substrates in different orientations.     

Crystal structure of the C-terminal three-helix bundle subdomain of C. elegans Hsp70

Hsp70 chaperones are composed of two domains; the 40 kDa N-terminal nucleotide-binding domain (NDB) and the 30 kDa C-terminal substrate-binding domain (SBD). Structures of the SBD from Escherichia coli homologues DnaK and HscA show it can be further divided into an 18 kDa beta-sandwich subdomain, which forms the hydrophobic binding pocket, and a 10 kDa C-terminal three-helix bundle that forms a lid over the binding pocket. Across prokaryotes and eukaryotes, the NBD and beta-sandwich subdomain are well conserved in both sequence and structure. The C-terminal subdomain is, however, more evolutionary variable and the only eukaryotic structure from rat Hsc70 revealed a diverged helix-loop-helix fold. We have solved the crystal structure of the C-terminal 10 kDa subdomain from Caenorhabditis elegans Hsp70 which forms a helical-bundle similar to the prokaryotic homologues. This provides the first confirmation of the structural conservation of this subdomain in eukaryotes. Comparison with the rat structure reveals a domain-swap dimerisation mechanism; however, the C. elegans subdomain exists exclusively as a monomer in solution in agreement with the hypothesis that regions out with the C-terminal subdomain are necessary for Hsp70 self-association.     

Structural determinants of HscA peptide-binding specificity

The Hsp70-class molecular chaperone HscA interacts specifically with a conserved (99)LPPVK(103) motif of the iron-sulfur cluster scaffold protein IscU. We used a cellulose-bound peptide array to perform single-site saturation substitution of peptide residues corresponding to Glu(98)-Ile(104) of IscU to determine positional amino acid requirements for recognition by HscA. Two mutant chaperone forms, HscA(F426A) with a DnaK-like arch structure and HscA(M433V) with a DnaK-like substrate-binding pocket, were also studied. Wild-type HscA and HscA(F426A) exhibited a strict preference for proline in the central peptide position (ELPPVKI), whereas HscA(M433V) bound a peptide containing a Pro-->Leu substitution at this location (ELPLVKI). Contributions of Phe(426) and Met(433) to HscA peptide specificity were further tested in solution using a fluorescence-based peptide-binding assay. Bimane-labeled HscA and HscA(F426A) bound ELPPVKI peptides with higher affinity than leucine-substituted peptides, whereas HscA(M433V) favored binding of ELPLVKI peptides. Fluorescence-binding studies were also carried out with derivatives of the peptide NRLLLTG, a model substrate for DnaK. HscA and HscA(F426A) bound NRLLLTG peptides weakly, whereas HscA(M433V) bound NRLLLTG peptides with higher affinity than IscU-derived peptides ELPPVKI and ELPLVKI. These results suggest that the specificity of HscA for the LPPVK recognition sequence is determined in part by steric obstruction of the hydrophobic binding pocket by Met(433) and that substitution with the Val(433) sidechain imparts a broader, more DnaK-like, substrate recognition pattern.     

Effect of evolution of the C-terminal region on chaperone activity of Hsp70

Dynamic interdomain interactions within the Hsp70 protein is the basis for the allosteric and functional properties of Hsp70s. While Hsp70s are generally conserved in terms of structure, allosteric behavior, and some overlapping functions, Hsp70s also contain variable sequence regions which are related to distinct functions. In the Hsp70 sequence, the part with the greatest sequence variation is the C-terminal α-helical lid subdomain of substrate-binding domain (SBDα) together with the intrinsically disordered region. Dynamic interactions between the SBDα and β-sandwich substrate-binding subdomain (SBDβ) contribute to the chaperone functions of Hsp70s by tuning kinetics of substrate binding. To investigate how the C-terminal region of Hsp70 has evolved from prokaryotic to eukaryotic organisms, we tested whether this region can be exchanged among different Hsp70 members to support basic chaperone functions. We found that this region from eukaryotic Hsp70 members cannot substitute for the same region in Escherichia coli DnaK to facilitate normal chaperone activity of DnaK. In contrast, this region from E. coli DnaK and Saccharomyces cerevisiae Hsp70 (Ssa1 and Ssa4) can partially support some roles of human stress inducible Hsp70 (hHsp70) and human cognate Hsp70 (hHsc70). Our results indicate that the C-terminal region from eukaryotic Hsp70 members cannot properly support SBDα–SBDβ interactions in DnaK, but this region from DnaK/Ssa1/Ssa4 can still form some SBDα–SBDβ interactions in hHsp70 or hHsc70, which suggests that the mode for SBDα–SBDβ interactions is different in prokaryotic and eukaryotic Hsp70 members. This study provides new insight in the divergency among different Hsp70 homologs and the evolution of Hsp70s.     

Physics-based modeling provides predictive understanding of selectively promiscuous substrate binding by Hsp70 chaperones

To help cells cope with protein misfolding and aggregation, Hsp70 molecular chaperones selectively bind a variety of sequences (“selective promiscuity”). Statistical analyses from substrate-derived peptide arrays reveal that DnaK, the E. coli Hsp70, binds to sequences containing three to five branched hydrophobic residues, although otherwise the specific amino acids can vary considerably. Several high-resolution structures of the substrate -binding domain (SBD) of DnaK bound to peptides reveal a highly conserved configuration of the bound substrate and further suggest that the substrate-binding cleft consists of five largely independent sites for interaction with five consecutive substrate residues. Importantly, both substrate backbone orientations (N- to C- and C- to N-) allow essentially the same backbone hydrogen-bonding and side-chain interactions with the chaperone. In order to rationalize these observations, we performed atomistic molecular dynamics simulations to sample the interactions of all 20 amino acid side chains in each of the five sites of the chaperone in the context of the conserved substrate backbone configurations. The resulting interaction energetics provide the basis set for deriving a predictive model that we call Paladin (Physics-based model of DnaK-Substrate Binding). Trained using available peptide array data, Paladin can distinguish binders and nonbinders of DnaK with accuracy comparable to existing predictors and further predicts the detailed configuration of the bound sequence. Tested using existing DnaK-peptide structures, Paladin correctly predicted the binding register in 10 out of 13 substrate sequences that bind in the N- to C- orientation, and the binding orientation in 16 out of 22 sequences. The physical basis of the Paladin model provides insight into the origins of how Hsp70s bind substrates with a balance of selectivity and promiscuity. The approach described here can be extended to other Hsp70s where extensive peptide array data is not available.     

Allosteric Coupling between the Lid and Interdomain Linker in DnaK Revealed by Inhibitor Binding Studies

The molecular chaperone DnaK assists protein folding and refolding, translocation across membranes, and regulation of the heat shock response. In Escherichia coli, the protein is a target for insect-derived antimicrobial peptides, pyrrhocoricins. We present here the X-ray crystallographic analysis of the E. coli DnaK substrate-binding domain in complex with pyrrhocoricin-derived peptide inhibitors. The structures show that pyrrhocoricins act as site-specific, dual-mode (competitive and allosteric) inhibitors, occupying the substrate-binding tunnel and disrupting the latch between the lid and the β-sandwich. Our structural analysis revealed an allosteric coupling between the movements of the lid and the interdomain linker, identifying a previously unknown mechanism of the lid-mediated regulation of the chaperone cycle.DnaK is the bacterial molecular chaperone from the Hsp70 (70-kDa heat shock protein) family that assists many cellular processes involving proteins in their nonnative conformations, such as folding of newly synthesized proteins, protein translocation across membranes, refolding of misfolded and aggregated proteins, degradation of unstable proteins, and regulation of the heat shock response (for reviews, see references 10, 28, and 42). The chaperone function of DnaK is based on its ability to transiently bind to exposed stretches of hydrophobic residues in partially or fully unfolded proteins in an ATP-controlled fashion, thereby preventing aggregation and misfolding. DnaK recognizes short peptide sequences containing up to five consecutive hydrophobic residues (with leucine found frequently in the middle), flanked preferentially by basic residues (42, 43). The molecular-chaperone activity is functionally linked with ATP hydrolysis; the substrate-binding and release cycle is driven by the switching between the ATP-bound state, with low affinity and a high exchange rate for substrates, and the ADP-bound state, with high affinity and a low exchange rate for substrates.In vivo, DnaK activity is supported by two cochaperones, GrpE, which facilitates the ADP/ATP exchange, and DnaJ, which stimulates ATP hydrolysis and thus aids the peptide capture (10, 25, 28, 38, 54). DnaJ itself also recognizes exposed stretches of hydrophobic residues in partially unfolded or denatured proteins, with specificity overlapping with that of DnaK (44). It is therefore thought that DnaJ serves as a scanning factor for DnaK by binding specific unfolded substrates and presenting them to the ATP-bound form of DnaK.Escherichia coli DnaK is composed of two domains: an N-terminal ATPase domain (residues 1 to 387) and a C-terminal substrate-binding domain (SBD) (residues 388 to 638) (10). The latter is made up of an 18-kDa β-sandwich subdomain that holds the substrate-binding cleft and a C-terminal α-helical-bundle “lid” subdomain that stabilizes the complex with the peptide substrate and controls the accessibility of the peptide binding site but does not interact with the substrate directly (5, 55). Removal of the lid subdomain by truncation decreases the affinity of DnaK for polypeptide substrates, primarily by increasing the dissociation rates (9, 28, 46, 47).The activities of the ATPase and the SBDs are allosterically coupled. ATP binding induces a global conformational change that results in the docking of the ATPase domain onto the SBD and opening of the latter, thus triggering the release of a peptide substrate (45, 46). Peptide binding, in turn, accelerates DnaK/DnaJ-mediated ATP hydrolysis, followed by trapping of the substrate and dissociation of the ATPase domain from the SBD. Upon the subsequent GrpE-mediated exchange of ADP for ATP, DnaK returns to the beginning of its molecular-chaperone cycle (references 6 and 28 and references therein). In this manner, DnaK alternates between the “open” (low-peptide-affinity) and closed (high-peptide-affinity) states. The detailed molecular mechanism of the allosteric interdomain communication is unknown, although the previous mutagenesis studies identified the conserved interdomain linker VLLL (389 to 392) (25), the segment 507 to 537 (32), and residue K414 (31) on the SBD surface as the structural elements that are required for signal transmission.Previous X-ray crystallographic and nuclear magnetic resonance studies of the SBD complex with the heptapeptide NR (NRLLLTG) provided an insight into the structural basis for the substrate recognition and amino acid sequence specificity of DnaK (48, 55). The peptide has been shown to bind in a short tunnel formed by the loops of the β-sandwich subdomain of the SBD in an extended conformation through hydrophobic and van der Waals side chain interactions and hydrogen bonds between the peptide backbones of the substrate and the SBD. These structures rationalized the ability of DnaK to differentiate between native and nonnative protein conformers by recognizing structural features common to nascent chains: an accessible peptide backbone and solvent-exposed aliphatic side chains.DnaK has been identified as a molecular target of pyrrhocoricin (l-PYR) (VDKGSYLPRPTPPRPIYNRN), an insect-derived antibacterial peptide (13, 23, 34). Nontoxicity to mammalian cells and good serum stability of l-PYR-derived peptides make them promising drug candidates in treating emerging/re-emerging antimicrobial-resistant bacterial pathogens (15, 35) and highlight the importance of detailed structural characterization of inhibitor-protein interactions with a view to rational drug design. This paper describes the first crystal structures of the E. coli DnaK SBD, truncated at the C terminus (residues 389 to 607), in complex with two l-PYR-derived peptidic inhibitors, one of which (the short peptide) displays nanomolar affinity for nucleotide-free E. coli DnaK (K_d [dissociation constant] = 5.5 nM, the lowest that has ever been reported for any peptide [M. Liebscher, unpublished data]).     

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.     

Characterization of a lidless form of the molecular chaperone DnaK: deletion of the lid increases peptide on- and off-rate constants

The C-terminal, polypeptide binding domain of the 70-kDa molecular chaperone DnaK is composed of a unique lidlike subdomain that appears to hinder steric access to the peptide binding site. We have expressed, purified, and characterized a lidless form of DnaK to test the influence of the lid on the ATPase activity, on interdomain communication, and on the kinetics of peptide binding. The principal findings are that loss of the lid creates an activated form of DnaK which is not equivalent to ATP-bound DnaK. For example, at 25 degrees C the NR peptide (NRLLLTG) dissociates from the ADP and ATP states of DnaK with observed off-rate constants of 0.001 and 4.8 s(-1), respectively. In contrast, for DnaK that lacks most of the helical lid, residues 518-638, the NR peptide dissociates with observed off-rate constants of 0.1 and 188 s(-1). These results show that the loss of the lid does not interfere with interdomain communication, that the beta-sandwich peptide binding domain can exist in two discrete conformations, and that the lid functions to increase the lifetime of a DnaK.peptide complex. We discuss several mechanisms to explain how the lid affects the lifetime of a DnaK.peptide complex.     

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.     

Modulation of substrate specificity of the DnaK chaperone by alteration of a hydrophobic arch

Hsp70 chaperones assist protein folding by reversible interaction with extended hydrophobic segments of substrate polypeptides. We investigated the contribution of three structural elements of the substrate- binding cavity of the Escherichia coli homologue, DnaK, to substrate specificity by investigating mutant DnaK proteins for binding to cellulose-bound peptides. Deletion of the C-terminal subdomain (Delta539-638) and blockage of the access to the hydrophobic pocket in the substrate-binding cavity (V436F) did not change the specificity, although the latter exchange reduced the affinity to all peptides investigated. Mutations (A429W, M404A/A429W) that affect the formation of a hydrophobic arch spanning over the bound substrate disfavored DnaK binding, especially to peptides with short stretches of consecutive hydrophobic residues flanked by acidic residues, while binding to most other peptides remained unchanged. The arch thus contributes to the substrate specificity of DnaK. This finding is of particular interest, since of all the residues of the substrate-binding cavity that contact bound substrate, only the arch-forming residues show significant variation within the Hsp70 family.     

The nucleotide‐bound/substrate‐bound conformation of the Mycoplasma genitalium DnaK chaperone

Hsp70 chaperones keep protein homeostasis facilitating the response of organisms to changes in external and internal conditions. Hsp70s have two domains—nucleotide binding domain (NBD) and substrate binding domain (SBD)—connected by a conserved hydrophobic linker. Functioning of Hsp70s depend on tightly regulated cycles of ATP hydrolysis allosterically coupled, often together with cochaperones, to the binding/release of peptide substrates. Here we describe the crystal structure of the Mycoplasma genitalium DnaK (MgDnaK) protein, an Hsp70 homolog, in the noncompact, nucleotide‐bound/substrate‐bound conformation. The MgDnaK structure resembles the one from the thermophilic eubacteria DnaK trapped in the same state. However, in MgDnaK the NBD and SBD domains remain close to each other despite the lack of direct interaction between them and with the linker contacting the two subdomains of SBD. These observations suggest that the structures might represent an intermediate of the protein where the conserved linker binds to the SBD to favor the noncompact state of the protein by stabilizing the SBDβ‐SBDα subdomains interaction, promoting the capacity of the protein to sample different conformations, which is critical for proper functioning of the molecular chaperone allosteric mechanism. Comparison of the solved structures indicates that the NBD remains essentially invariant in presence or absence of nucleotide.     

Role of the DnaK and HscA homologs of Hsp70 chaperones in protein folding in E.coli.

Folding of newly synthesized cytosolic proteins has been proposed to require assistance by Hsp70 chaperones. We investigated whether two Hsp70 homologs of Escherichia coli, DnaK and HscA, have this role in vivo. Double mutants lacking dnaK and hscA were viable and lacked defects in protein folding at intermediate temperature. After heat shock, a subpopulation of pre-existing proteins slowly aggregated in mutants lacking DnaK, but not HscA, whereas the bulk of newly synthesized proteins displayed wild-type solubility. For thermolabile firefly luciferase, DnaK was dispensable for de novo folding at 30 degrees C, but essential for aggregation prevention during heat shock and subsequent refolding. DnaK and HscA are thus not strictly essential for folding of newly synthesized proteins. DnaK instead has functions in refolding of misfolded proteins that are essential under stress.     

Insights into the influence of nucleotides on actin family proteins from seven structures of Arp2/3 complex

ATP is required for nucleation of actin filament branches by Arp2/3 complex, but the influence of ATP binding and hydrolysis are poorly understood. We determined crystal structures of bovine Arp2/3 complex cocrystallized with various bound adenine nucleotides and cations. Nucleotide binding favors closure of the nucleotide-binding cleft of Arp3, but no large-scale conformational changes in the complex. Thus, ATP binding does not directly activate Arp2/3 complex but is part of a network of interactions that contribute to nucleation. We compared nucleotide-induced conformational changes of residues lining the cleft in Arp3 and actin structures to construct a movie depicting the proposed ATPase cycle for the actin family. Chemical crosslinking stabilized subdomain 1 of Arp2, revealing new electron density for 69 residues in this subdomain. Steric clashes with Arp3 appear to be responsible for intrinsic disorder of subdomains 1 and 2 of Arp2 in inactive Arp2/3 complex.     

Regulation of the HscA ATPase reaction cycle by the co-chaperone HscB and the iron-sulfur cluster assembly protein IscU

The ATPase activity of HscA, a specialized hsp70 molecular chaperone from Escherichia coli, is regulated by the iron-sulfur cluster assembly protein IscU and the J-type co-chaperone HscB. IscU behaves as a substrate for HscA, and HscB enhances the binding of IscU to HscA. To better understand the mechanism by which HscB and IscU regulate HscA, we examined binding of HscB to the different conformational states of HscA and the effects of HscB and IscU on the kinetics of the individual steps of the HscA ATPase reaction cycle. Affinity sensor studies revealed that whereas IscU binds both ADP (R-state) and ATP (T-state) HscA complexes, HscB interacts only with an ATP-bound state. Studies of ATPase activity under single-turnover and rapid mixing conditions showed that both IscU and HscB interact with the low peptide affinity T-state of HscA (HscA++.ATP) and that both modestly accelerate (3-10-fold) the rate-determining steps in the HscA reaction cycle, k(hyd) and k(T-->R). When present together, IscU and HscB synergistically stimulate both k(hyd) (approximately = 500-fold) and k(T-->R) (approximately = 60-fold), leading to enhanced formation of the HscA.ADP-IscU complex (substrate capture). Following ADP/ATP exchange, IscU also stimulates k(R-->T) (approximately = 50-fold) and thereby accelerates the rate at which the low peptide affinity HscA++.ATP T-state is regenerated. Because HscA nucleotide exchange is fast, the overall rate of the chaperone cycle in vivo will be determined by the availability of the IscU-HscB substrate-co-chaperone complex.     

Empirical calculation of the relative free energies of peptide binding to the molecular chaperone DnaK

We describe a methodology to calculate the relative free energies of protein-peptide complex formation. The interaction energy was decomposed into nonpolar, electrostatic and entropic contributions. A free energy-surface area relationship served to calculate the nonpolar free energy term. The electrostatic free energy was calculated with the finite difference Poisson-Boltzmann method and the entropic contribution was estimated from the loss in the conformational entropy of the peptide side chains. We applied this methodology to a series of DnaK*peptide complexes. On the basis of the single known crystal structure of the peptide-binding domain of DnaK with a bound heptapeptide, we modeled ten other DnaK*heptapeptide complexes with experimentally measured K(d) values from 0.06 microM to 11 microM, using molecular dynamics to refine the structures of the complexes. Molecular dynamic trajectories, after equilibration, were used for calculating the energies with greater accuracy. The calculated relative binding free energies were compared with the experimentally determined free energies. Linear scaling of the calculated terms was applied to fit them to the experimental values. The calculated binding free energies were between -7.1 kcal/mol and - 9.4 kcal/mol with a correlation coefficient of 0.86. The calculated nonpolar contributions are mainly due to the central hydrophobic binding pocket of DnaK for three amino acid residues. Negative electrostatic fields generated by the protein increase the binding affinity for basic residues flanking the hydrophobic core of the peptide ligand. Analysis of the individual energy contributions indicated that the nonpolar contributions are predominant compared to the other energy terms even for peptides with low affinity and that inclusion of the change in conformational entropy of the peptide side chains does not improve the discriminative power of the calculation. The method seems to be useful for predicting relative binding energies of peptide ligands of DnaK and might be applicable to other protein-peptide systems, particularly if only the structure of one protein-ligand complex is available.     

Network of protein-protein interactions among iron-sulfur cluster assembly proteins in Escherichia coli

The assembly of iron-sulfur (Fe-S) clusters is mediated by complex machinery which, in Escherichia coli, is encoded by the iscRSUA-hscBA-fdx-ORF3 gene cluster. Here, we demonstrate the network of protein-protein interactions among the components involved in the machinery. We have constructed (His)(6)-tagged versions of the components and identified their interacting partners that were co-purified from E. coli extracts with a Ni-affinity column. Direct associations of the defined pair of proteins were further examined in yeast cells using the two-hybrid system. In accord with the previous in vitro binding and kinetic experiments, interactions were observed for the combinations of IscS and IscU, IscU and HscB, IscU and HscA, and HscB and HscA. In addition, we have identified previously unreported interactions between IscS and Fdx, IscS and ORF3, IscA and HscA, and HscA and Fdx. We also found, by site-directed mutational analysis combined with the two-hybrid system, that two cysteine residues in IscU are essential for binding with HscB but not with IscS. Despite the complex network of interactions in various combinations of components, heteromultimeric complexes were not observed in our experiments except for the putative oligomeric form of IscU-IscS-ORF3. Thus, the sequential association and dissociation among the IscS, IscU, IscA, HscB, HscA, Fdx, and ORF3 proteins may be a critical process in the assembly of Fe-S clusters.     

Interaction between heat shock proteins and antimicrobial peptides

Drosocin, pyrrhocoricin, and apidaecin, representing the short (18-20 amino acid residues) proline-rich antibacterial peptide family, originally isolated from insects, were shown to act on a target bacterial protein in a stereospecific manner. Native pyrrhocoricin and one of its analogues designed for this purpose protect mice from bacterial challenge and, therefore, may represent alternatives to existing antimicrobial drugs. Furthermore, this mode of action can be a basis for the design of a completely novel set of antibacterial compounds, peptidic or peptidomimetic, if the interacting bacterial biopolymers are known. Recently, apidaecin was shown to enter Escherichia coli and subsequently kill bacteria through sequential interactions with diverse target macromolecules. In this paper report, we used biotin- and fluorescein-labeled pyrrhocoricin, drosocin, and apidaecin analogues to identify biopolymers that bind to these peptides and are potentially involved in the above-mentioned multistep killing process. Through use of a biotin-labeled pyrrhocoricin analogue, we isolated two interacting proteins from E. coli. According to mass spectrometry, Western blot, and fluorescence polarization, the short, proline-rich peptides bound to DnaK, the 70-kDa bacterial heat shock protein, both in solution and on the solid-phase. GroEL, the 60-kDa chaperonin, also bound in solution. Control experiments with an unrelated labeled peptide showed that while binding to DnaK was specific for the antibacterial peptides, binding to GroEL was not specific for these insect sequences. The killing of bacteria and DnaK binding are related events, as an inactive pyrrhocoricin analogue made of all-D-amino acids failed to bind. The pharmaceutical potential of the insect antibacterial peptides is underscored by the fact that pyrrhocoricin did not bind to Hsp70, the human equivalent of DnaK. Competition assay with unlabeled pyrrhocoricin indicated differences in GroEL and DnaK binding and a probable two-site interaction with DnaK. In addition, all three antibacterial peptides strongly interacted with two bacterial lipopolysaccharide (LPS) preparations in solution, indicating that the initial step of the bacterial killing cascade proceeds through LPS-mediated cell entry.     

Deletion of DnaK's lid strengthens binding to the nucleotide exchange factor,GrpE: a kinetic and thermodynamic analysis

In this study, we have used surface plasmon resonance (SPR) and isothermal microtitration calorimetry (ITC) to study the mechanism of complex formation between the Hsp70 molecular chaperone, DnaK, and its cochaperone, GrpE, which is a nucleotide exchange factor. Experiments were geared toward understanding the influence of DnaK's three domains, the ATPase (residues 1-388), substrate-binding (residues 393-507), and lid (residues 508-638) domains, on complex formation with GrpE. We show that the equilibrium dissociation constants for the interaction of GrpE with wtDnaK, lidless DnaK(2-517), the ATPase domain (2-388), and the substrate-binding fragment (393-507) are 64 (+/-16) nM, 4.0 (+/-1.5) nM, 35 (+/-10) nM, and 67 (+/-11) microM, respectively, and that the on-rate constant for the different reactions varies by over 4 orders of magnitude. SPR experiments revealed that GrpE-DnaK(393-507) complex formation is inhibited by added peptide and abolished when the 33-residue flexible "tail" of GrpE is deleted. Such results strongly suggest that the 33-residue flexible N-terminal tail of GrpE binds in the substrate-binding pocket of DnaK. This unique mode of binding between GrpE's tail and DnaK contributes to, but does not fully explain, the decrease in K(d) from 64 to 4 nM upon deletion of DnaK's lid. The possibility that deletion of DnaK's lid creates a more symmetrically shaped molecule, with enhanced affinity to GrpE, is also discussed. Our results reveal a complex set of molecular interactions between DnaK and its cochaperone GrpE. We discuss the impact of each domain on complex formation and dissociation.